332 lines
9.4 KiB
C
332 lines
9.4 KiB
C
/*
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* Copyright (c) 2010-2014 Wind River Systems, Inc.
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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/**
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* @file
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* @brief Floating point register sharing routines
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*
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* This module allows multiple preemptible threads to safely share the system's
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* floating point registers, by allowing the system to save FPU state info
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* in a thread's stack region when a preemptive context switch occurs.
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*
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* Note: If the kernel has been built without floating point register sharing
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* support (CONFIG_FPU_SHARING), the floating point registers can still be used
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* safely by one or more cooperative threads OR by a single preemptive thread,
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* but not by both.
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*
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* This code is not necessary for systems with CONFIG_EAGER_FPU_SHARING, as
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* the floating point context is unconditionally saved/restored with every
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* context switch.
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*
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* The floating point register sharing mechanism is designed for minimal
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* intrusiveness. Floating point state saving is only performed for threads
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* that explicitly indicate they are using FPU registers, to avoid impacting
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* the stack size requirements of all other threads. Also, the SSE registers
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* are only saved for threads that actually used them. For those threads that
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* do require floating point state saving, a "lazy save/restore" mechanism
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* is employed so that the FPU's register sets are only switched in and out
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* when absolutely necessary; this avoids wasting effort preserving them when
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* there is no risk that they will be altered, or when there is no need to
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* preserve their contents.
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*
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* WARNING
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* The use of floating point instructions by ISRs is not supported by the
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* kernel.
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*
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* INTERNAL
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* The kernel sets CR0[TS] to 0 only for threads that require FP register
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* sharing. All other threads have CR0[TS] set to 1 so that an attempt
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* to perform an FP operation will cause an exception, allowing the kernel
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* to enable FP register sharing on its behalf.
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*/
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#include <kernel.h>
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#include <kernel_internal.h>
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/* SSE control/status register default value (used by assembler code) */
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extern uint32_t _sse_mxcsr_default_value;
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/**
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*
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* @brief Disallow use of floating point capabilities
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*
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* This routine sets CR0[TS] to 1, which disallows the use of FP instructions
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* by the currently executing thread.
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*
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* @return N/A
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*/
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static inline void z_FpAccessDisable(void)
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{
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void *tempReg;
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__asm__ volatile(
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"movl %%cr0, %0;\n\t"
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"orl $0x8, %0;\n\t"
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"movl %0, %%cr0;\n\t"
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: "=r"(tempReg)
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:
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: "memory");
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}
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/**
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*
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* @brief Save non-integer context information
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*
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* This routine saves the system's "live" non-integer context into the
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* specified area. If the specified thread supports SSE then
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* x87/MMX/SSEx thread info is saved, otherwise only x87/MMX thread is saved.
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* Function is invoked by FpCtxSave(struct k_thread *thread)
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*
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* @return N/A
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*/
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static inline void z_do_fp_regs_save(void *preemp_float_reg)
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{
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__asm__ volatile("fnsave (%0);\n\t"
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:
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: "r"(preemp_float_reg)
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: "memory");
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}
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/**
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*
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* @brief Save non-integer context information
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*
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* This routine saves the system's "live" non-integer context into the
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* specified area. If the specified thread supports SSE then
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* x87/MMX/SSEx thread info is saved, otherwise only x87/MMX thread is saved.
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* Function is invoked by FpCtxSave(struct k_thread *thread)
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*
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* @return N/A
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*/
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static inline void z_do_fp_and_sse_regs_save(void *preemp_float_reg)
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{
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__asm__ volatile("fxsave (%0);\n\t"
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:
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: "r"(preemp_float_reg)
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: "memory");
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}
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/**
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*
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* @brief Initialize floating point register context information.
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*
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* This routine initializes the system's "live" floating point registers.
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*
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* @return N/A
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*/
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static inline void z_do_fp_regs_init(void)
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{
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__asm__ volatile("fninit\n\t");
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}
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/**
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*
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* @brief Initialize SSE register context information.
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*
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* This routine initializes the system's "live" SSE registers.
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*
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* @return N/A
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*/
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static inline void z_do_sse_regs_init(void)
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{
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__asm__ volatile("ldmxcsr _sse_mxcsr_default_value\n\t");
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}
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/*
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* Save a thread's floating point context information.
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*
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* This routine saves the system's "live" floating point context into the
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* specified thread control block. The SSE registers are saved only if the
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* thread is actually using them.
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*/
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static void FpCtxSave(struct k_thread *thread)
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{
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#ifdef CONFIG_SSE
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if ((thread->base.user_options & K_SSE_REGS) != 0) {
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z_do_fp_and_sse_regs_save(&thread->arch.preempFloatReg);
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return;
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}
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#endif
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z_do_fp_regs_save(&thread->arch.preempFloatReg);
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}
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/*
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* Initialize a thread's floating point context information.
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*
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* This routine initializes the system's "live" floating point context.
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* The SSE registers are initialized only if the thread is actually using them.
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*/
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static inline void FpCtxInit(struct k_thread *thread)
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{
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z_do_fp_regs_init();
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#ifdef CONFIG_SSE
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if ((thread->base.user_options & K_SSE_REGS) != 0) {
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z_do_sse_regs_init();
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}
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#endif
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}
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/*
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* Enable preservation of floating point context information.
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*
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* The transition from "non-FP supporting" to "FP supporting" must be done
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* atomically to avoid confusing the floating point logic used by z_swap(), so
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* this routine locks interrupts to ensure that a context switch does not occur.
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* The locking isn't really needed when the routine is called by a cooperative
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* thread (since context switching can't occur), but it is harmless.
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*/
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void k_float_enable(struct k_thread *thread, unsigned int options)
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{
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unsigned int imask;
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struct k_thread *fp_owner;
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/* Ensure a preemptive context switch does not occur */
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imask = irq_lock();
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/* Indicate thread requires floating point context saving */
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thread->base.user_options |= (uint8_t)options;
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/*
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* The current thread might not allow FP instructions, so clear CR0[TS]
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* so we can use them. (CR0[TS] gets restored later on, if necessary.)
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*/
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__asm__ volatile("clts\n\t");
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/*
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* Save existing floating point context (since it is about to change),
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* but only if the FPU is "owned" by an FP-capable task that is
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* currently handling an interrupt or exception (meaning its FP context
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* must be preserved).
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*/
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fp_owner = _kernel.current_fp;
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if (fp_owner != NULL) {
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if ((fp_owner->arch.flags & X86_THREAD_FLAG_ALL) != 0) {
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FpCtxSave(fp_owner);
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}
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}
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/* Now create a virgin FP context */
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FpCtxInit(thread);
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/* Associate the new FP context with the specified thread */
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if (thread == _current) {
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/*
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* When enabling FP support for the current thread, just claim
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* ownership of the FPU and leave CR0[TS] unset.
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*
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* (The FP context is "live" in hardware, not saved in TCS.)
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*/
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_kernel.current_fp = thread;
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} else {
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/*
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* When enabling FP support for someone else, assign ownership
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* of the FPU to them (unless we need it ourselves).
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*/
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if ((_current->base.user_options & _FP_USER_MASK) == 0) {
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/*
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* We are not FP-capable, so mark FPU as owned by the
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* thread we've just enabled FP support for, then
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* disable our own FP access by setting CR0[TS] back
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* to its original state.
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*/
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_kernel.current_fp = thread;
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z_FpAccessDisable();
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} else {
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/*
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* We are FP-capable (and thus had FPU ownership on
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* entry), so save the new FP context in their TCS,
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* leave FPU ownership with self, and leave CR0[TS]
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* unset.
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*
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* The saved FP context is needed in case the thread
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* we enabled FP support for is currently pre-empted,
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* since z_swap() uses it to restore FP context when
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* the thread re-activates.
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*
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* Saving the FP context reinits the FPU, and thus
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* our own FP context, but that's OK since it didn't
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* need to be preserved. (i.e. We aren't currently
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* handling an interrupt or exception.)
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*/
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FpCtxSave(thread);
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}
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}
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irq_unlock(imask);
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}
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/**
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* Disable preservation of floating point context information.
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*
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* The transition from "FP supporting" to "non-FP supporting" must be done
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* atomically to avoid confusing the floating point logic used by z_swap(), so
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* this routine locks interrupts to ensure that a context switch does not occur.
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* The locking isn't really needed when the routine is called by a cooperative
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* thread (since context switching can't occur), but it is harmless.
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*/
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int z_float_disable(struct k_thread *thread)
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{
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unsigned int imask;
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/* Ensure a preemptive context switch does not occur */
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imask = irq_lock();
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/* Disable all floating point capabilities for the thread */
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thread->base.user_options &= ~_FP_USER_MASK;
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if (thread == _current) {
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z_FpAccessDisable();
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_kernel.current_fp = (struct k_thread *)0;
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} else {
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if (_kernel.current_fp == thread) {
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_kernel.current_fp = (struct k_thread *)0;
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}
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}
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irq_unlock(imask);
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return 0;
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}
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/*
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* Handler for "device not available" exception.
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*
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* This routine is registered to handle the "device not available" exception
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* (vector = 7).
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*
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* The processor will generate this exception if any x87 FPU, MMX, or SSEx
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* instruction is executed while CR0[TS]=1. The handler then enables the
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* current thread to use all supported floating point registers.
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*/
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void _FpNotAvailableExcHandler(z_arch_esf_t *pEsf)
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{
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ARG_UNUSED(pEsf);
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/*
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* Assume the exception did not occur in an ISR.
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* (In other words, CPU cycles will not be consumed to perform
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* error checking to ensure the exception was not generated in an ISR.)
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*/
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/* Enable highest level of FP capability configured into the kernel */
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k_float_enable(_current, _FP_USER_MASK);
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}
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_EXCEPTION_CONNECT_NOCODE(_FpNotAvailableExcHandler, IV_DEVICE_NOT_AVAILABLE);
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