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adcc81f148
Mapping the delay slot emulation page as both writeable & executable
presents a security risk, in that if an exploit can write to & jump into
the page then it can be used as an easy way to execute arbitrary code.
Prevent this by mapping the page read-only for userland, and using
access_process_vm() with the FOLL_FORCE flag to write to it from
mips_dsemul().
This will likely be less efficient due to copy_to_user_page() performing
cache maintenance on a whole page, rather than a single line as in the
previous use of flush_cache_sigtramp(). However this delay slot
emulation code ought not to be running in any performance critical paths
anyway so this isn't really a problem, and we can probably do better in
copy_to_user_page() anyway in future.
A major advantage of this approach is that the fix is small & simple to
backport to stable kernels.
Reported-by: Andy Lutomirski <luto@kernel.org>
Signed-off-by: Paul Burton <paul.burton@mips.com>
Fixes: 432c6bacbd
("MIPS: Use per-mm page to execute branch delay slot instructions")
Cc: stable@vger.kernel.org # v4.8+
Cc: linux-mips@vger.kernel.org
Cc: linux-kernel@vger.kernel.org
Cc: Rich Felker <dalias@libc.org>
Cc: David Daney <david.daney@cavium.com>
309 lines
9.1 KiB
C
309 lines
9.1 KiB
C
// SPDX-License-Identifier: GPL-2.0
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#include <linux/err.h>
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#include <linux/slab.h>
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#include <linux/mm_types.h>
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#include <linux/sched/task.h>
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#include <asm/branch.h>
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#include <asm/cacheflush.h>
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#include <asm/fpu_emulator.h>
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#include <asm/inst.h>
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#include <asm/mipsregs.h>
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#include <linux/uaccess.h>
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/**
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* struct emuframe - The 'emulation' frame structure
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* @emul: The instruction to 'emulate'.
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* @badinst: A break instruction to cause a return to the kernel.
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*
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* This structure defines the frames placed within the delay slot emulation
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* page in response to a call to mips_dsemul(). Each thread may be allocated
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* only one frame at any given time. The kernel stores within it the
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* instruction to be 'emulated' followed by a break instruction, then
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* executes the frame in user mode. The break causes a trap to the kernel
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* which leads to do_dsemulret() being called unless the instruction in
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* @emul causes a trap itself, is a branch, or a signal is delivered to
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* the thread. In these cases the allocated frame will either be reused by
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* a subsequent delay slot 'emulation', or be freed during signal delivery or
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* upon thread exit.
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*
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* This approach is used because:
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*
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* - Actually emulating all instructions isn't feasible. We would need to
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* be able to handle instructions from all revisions of the MIPS ISA,
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* all ASEs & all vendor instruction set extensions. This would be a
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* whole lot of work & continual maintenance burden as new instructions
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* are introduced, and in the case of some vendor extensions may not
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* even be possible. Thus we need to take the approach of actually
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* executing the instruction.
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*
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* - We must execute the instruction within user context. If we were to
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* execute the instruction in kernel mode then it would have access to
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* kernel resources without very careful checks, leaving us with a
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* high potential for security or stability issues to arise.
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*
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* - We used to place the frame on the users stack, but this requires
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* that the stack be executable. This is bad for security so the
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* per-process page is now used instead.
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*
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* - The instruction in @emul may be something entirely invalid for a
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* delay slot. The user may (intentionally or otherwise) place a branch
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* in a delay slot, or a kernel mode instruction, or something else
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* which generates an exception. Thus we can't rely upon the break in
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* @badinst always being hit. For this reason we track the index of the
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* frame allocated to each thread, allowing us to clean it up at later
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* points such as signal delivery or thread exit.
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*
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* - The user may generate a fake struct emuframe if they wish, invoking
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* the BRK_MEMU break instruction themselves. We must therefore not
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* trust that BRK_MEMU means there's actually a valid frame allocated
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* to the thread, and must not allow the user to do anything they
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* couldn't already.
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*/
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struct emuframe {
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mips_instruction emul;
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mips_instruction badinst;
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};
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static const int emupage_frame_count = PAGE_SIZE / sizeof(struct emuframe);
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static inline __user struct emuframe *dsemul_page(void)
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{
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return (__user struct emuframe *)STACK_TOP;
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}
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static int alloc_emuframe(void)
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{
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mm_context_t *mm_ctx = ¤t->mm->context;
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int idx;
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retry:
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spin_lock(&mm_ctx->bd_emupage_lock);
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/* Ensure we have an allocation bitmap */
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if (!mm_ctx->bd_emupage_allocmap) {
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mm_ctx->bd_emupage_allocmap =
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kcalloc(BITS_TO_LONGS(emupage_frame_count),
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sizeof(unsigned long),
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GFP_ATOMIC);
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if (!mm_ctx->bd_emupage_allocmap) {
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idx = BD_EMUFRAME_NONE;
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goto out_unlock;
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}
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}
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/* Attempt to allocate a single bit/frame */
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idx = bitmap_find_free_region(mm_ctx->bd_emupage_allocmap,
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emupage_frame_count, 0);
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if (idx < 0) {
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/*
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* Failed to allocate a frame. We'll wait until one becomes
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* available. We unlock the page so that other threads actually
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* get the opportunity to free their frames, which means
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* technically the result of bitmap_full may be incorrect.
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* However the worst case is that we repeat all this and end up
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* back here again.
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*/
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spin_unlock(&mm_ctx->bd_emupage_lock);
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if (!wait_event_killable(mm_ctx->bd_emupage_queue,
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!bitmap_full(mm_ctx->bd_emupage_allocmap,
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emupage_frame_count)))
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goto retry;
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/* Received a fatal signal - just give in */
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return BD_EMUFRAME_NONE;
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}
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/* Success! */
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pr_debug("allocate emuframe %d to %d\n", idx, current->pid);
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out_unlock:
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spin_unlock(&mm_ctx->bd_emupage_lock);
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return idx;
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}
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static void free_emuframe(int idx, struct mm_struct *mm)
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{
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mm_context_t *mm_ctx = &mm->context;
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spin_lock(&mm_ctx->bd_emupage_lock);
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pr_debug("free emuframe %d from %d\n", idx, current->pid);
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bitmap_clear(mm_ctx->bd_emupage_allocmap, idx, 1);
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/* If some thread is waiting for a frame, now's its chance */
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wake_up(&mm_ctx->bd_emupage_queue);
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spin_unlock(&mm_ctx->bd_emupage_lock);
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}
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static bool within_emuframe(struct pt_regs *regs)
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{
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unsigned long base = (unsigned long)dsemul_page();
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if (regs->cp0_epc < base)
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return false;
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if (regs->cp0_epc >= (base + PAGE_SIZE))
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return false;
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return true;
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}
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bool dsemul_thread_cleanup(struct task_struct *tsk)
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{
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int fr_idx;
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/* Clear any allocated frame, retrieving its index */
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fr_idx = atomic_xchg(&tsk->thread.bd_emu_frame, BD_EMUFRAME_NONE);
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/* If no frame was allocated, we're done */
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if (fr_idx == BD_EMUFRAME_NONE)
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return false;
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task_lock(tsk);
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/* Free the frame that this thread had allocated */
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if (tsk->mm)
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free_emuframe(fr_idx, tsk->mm);
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task_unlock(tsk);
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return true;
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}
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bool dsemul_thread_rollback(struct pt_regs *regs)
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{
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struct emuframe __user *fr;
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int fr_idx;
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/* Do nothing if we're not executing from a frame */
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if (!within_emuframe(regs))
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return false;
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/* Find the frame being executed */
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fr_idx = atomic_read(¤t->thread.bd_emu_frame);
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if (fr_idx == BD_EMUFRAME_NONE)
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return false;
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fr = &dsemul_page()[fr_idx];
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/*
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* If the PC is at the emul instruction, roll back to the branch. If
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* PC is at the badinst (break) instruction, we've already emulated the
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* instruction so progress to the continue PC. If it's anything else
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* then something is amiss & the user has branched into some other area
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* of the emupage - we'll free the allocated frame anyway.
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*/
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if (msk_isa16_mode(regs->cp0_epc) == (unsigned long)&fr->emul)
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regs->cp0_epc = current->thread.bd_emu_branch_pc;
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else if (msk_isa16_mode(regs->cp0_epc) == (unsigned long)&fr->badinst)
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regs->cp0_epc = current->thread.bd_emu_cont_pc;
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atomic_set(¤t->thread.bd_emu_frame, BD_EMUFRAME_NONE);
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free_emuframe(fr_idx, current->mm);
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return true;
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}
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void dsemul_mm_cleanup(struct mm_struct *mm)
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{
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mm_context_t *mm_ctx = &mm->context;
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kfree(mm_ctx->bd_emupage_allocmap);
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}
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int mips_dsemul(struct pt_regs *regs, mips_instruction ir,
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unsigned long branch_pc, unsigned long cont_pc)
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{
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int isa16 = get_isa16_mode(regs->cp0_epc);
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mips_instruction break_math;
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unsigned long fr_uaddr;
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struct emuframe fr;
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int fr_idx, ret;
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/* NOP is easy */
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if (ir == 0)
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return -1;
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/* microMIPS instructions */
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if (isa16) {
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union mips_instruction insn = { .word = ir };
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/* NOP16 aka MOVE16 $0, $0 */
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if ((ir >> 16) == MM_NOP16)
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return -1;
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/* ADDIUPC */
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if (insn.mm_a_format.opcode == mm_addiupc_op) {
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unsigned int rs;
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s32 v;
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rs = (((insn.mm_a_format.rs + 0xe) & 0xf) + 2);
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v = regs->cp0_epc & ~3;
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v += insn.mm_a_format.simmediate << 2;
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regs->regs[rs] = (long)v;
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return -1;
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}
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}
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pr_debug("dsemul 0x%08lx cont at 0x%08lx\n", regs->cp0_epc, cont_pc);
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/* Allocate a frame if we don't already have one */
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fr_idx = atomic_read(¤t->thread.bd_emu_frame);
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if (fr_idx == BD_EMUFRAME_NONE)
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fr_idx = alloc_emuframe();
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if (fr_idx == BD_EMUFRAME_NONE)
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return SIGBUS;
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/* Retrieve the appropriately encoded break instruction */
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break_math = BREAK_MATH(isa16);
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/* Write the instructions to the frame */
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if (isa16) {
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union mips_instruction _emul = {
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.halfword = { ir >> 16, ir }
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};
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union mips_instruction _badinst = {
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.halfword = { break_math >> 16, break_math }
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};
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fr.emul = _emul.word;
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fr.badinst = _badinst.word;
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} else {
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fr.emul = ir;
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fr.badinst = break_math;
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}
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/* Write the frame to user memory */
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fr_uaddr = (unsigned long)&dsemul_page()[fr_idx];
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ret = access_process_vm(current, fr_uaddr, &fr, sizeof(fr),
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FOLL_FORCE | FOLL_WRITE);
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if (unlikely(ret != sizeof(fr))) {
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MIPS_FPU_EMU_INC_STATS(errors);
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free_emuframe(fr_idx, current->mm);
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return SIGBUS;
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}
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/* Record the PC of the branch, PC to continue from & frame index */
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current->thread.bd_emu_branch_pc = branch_pc;
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current->thread.bd_emu_cont_pc = cont_pc;
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atomic_set(¤t->thread.bd_emu_frame, fr_idx);
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/* Change user register context to execute the frame */
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regs->cp0_epc = fr_uaddr | isa16;
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return 0;
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}
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bool do_dsemulret(struct pt_regs *xcp)
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{
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/* Cleanup the allocated frame, returning if there wasn't one */
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if (!dsemul_thread_cleanup(current)) {
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MIPS_FPU_EMU_INC_STATS(errors);
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return false;
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}
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/* Set EPC to return to post-branch instruction */
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xcp->cp0_epc = current->thread.bd_emu_cont_pc;
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pr_debug("dsemulret to 0x%08lx\n", xcp->cp0_epc);
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MIPS_FPU_EMU_INC_STATS(ds_emul);
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return true;
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}
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