/* * Copyright (c) 2010-2014 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief Interrupt support for IA-32 arch * * INTERNAL * The _idt_base_address symbol is used to determine the base address of the IDT. * (It is generated by the linker script, and doesn't correspond to an actual * global variable.) */ #include #include #include #include #include #include #include #include #include extern void z_SpuriousIntHandler(void *handler); extern void z_SpuriousIntNoErrCodeHandler(void *handler); /* * Place the addresses of the spurious interrupt handlers into the intList * section. The genIdt tool can then populate any unused vectors with * these routines. */ void *__attribute__((section(".spurIsr"))) MK_ISR_NAME(z_SpuriousIntHandler) = &z_SpuriousIntHandler; void *__attribute__((section(".spurNoErrIsr"))) MK_ISR_NAME(z_SpuriousIntNoErrCodeHandler) = &z_SpuriousIntNoErrCodeHandler; __pinned_func void arch_isr_direct_footer_swap(unsigned int key) { (void)z_swap_irqlock(key); } #if CONFIG_X86_DYNAMIC_IRQ_STUBS > 0 /* * z_interrupt_vectors_allocated[] bitfield is generated by the 'gen_idt' tool. * It is initialized to identify which interrupts have been statically * connected and which interrupts are available to be dynamically connected at * run time, with a 1 bit indicating a free vector. The variable itself is * defined in the linker file. */ extern unsigned int z_interrupt_vectors_allocated[]; struct dyn_irq_info { /** IRQ handler */ void (*handler)(const void *param); /** Parameter to pass to the handler */ const void *param; }; /* * Instead of creating a large sparse table mapping all possible IDT vectors * to dyn_irq_info, the dynamic stubs push a "stub id" onto the stack * which is used by common_dynamic_handler() to fetch the appropriate * information out of this much smaller table */ __pinned_bss static struct dyn_irq_info dyn_irq_list[CONFIG_X86_DYNAMIC_IRQ_STUBS]; __pinned_bss static unsigned int next_irq_stub; /* Memory address pointing to where in ROM the code for the dynamic stubs are. * Linker symbol. */ extern char z_dynamic_stubs_begin[]; /** * @brief Allocate a free interrupt vector given * * This routine scans the z_interrupt_vectors_allocated[] array for a free vector * that satisfies the specified . * * This routine assumes that the relationship between interrupt priority and * interrupt vector is : * * priority = (vector / 16) - 2; * * Vectors 0 to 31 are reserved for CPU exceptions and do NOT fall under * the priority scheme. The first vector used for priority level 0 will be 32. * Each interrupt priority level contains 16 vectors. * * It is also assumed that the interrupt controllers are capable of managing * interrupt requests on a per-vector level as opposed to a per-priority level. * For example, the local APIC on Pentium4 and later processors, the in-service * register (ISR) and the interrupt request register (IRR) are 256 bits wide. * * @return allocated interrupt vector */ static unsigned int priority_to_free_vector(unsigned int requested_priority) { unsigned int entry; unsigned int fsb; /* first set bit in entry */ unsigned int search_set; unsigned int vector_block; unsigned int vector; static unsigned int mask[2] = {0x0000ffffU, 0xffff0000U}; vector_block = requested_priority + 2; __ASSERT(((vector_block << 4) + 15) <= CONFIG_IDT_NUM_VECTORS, "IDT too small (%d entries) to use priority %d", CONFIG_IDT_NUM_VECTORS, requested_priority); /* * Atomically allocate a vector from the * z_interrupt_vectors_allocated[] array to prevent race conditions * with other threads attempting to allocate an interrupt * vector. * * Note: As z_interrupt_vectors_allocated[] is initialized by the * 'gen_idt.py' tool, it is critical that this routine use the same * algorithm as the 'gen_idt.py' tool for allocating interrupt vectors. */ entry = vector_block >> 1; /* * The z_interrupt_vectors_allocated[] entry indexed by 'entry' * is a 32-bit quantity and thus represents the vectors for a pair of * priority levels. Mask out the unwanted priority level and then use * find_lsb_set() to scan for an available vector of the requested * priority. * * Note that find_lsb_set() returns bit position from 1 to 32, or 0 if * the argument is zero. */ search_set = mask[vector_block & 1] & z_interrupt_vectors_allocated[entry]; fsb = find_lsb_set(search_set); __ASSERT(fsb != 0U, "No remaning vectors for priority level %d", requested_priority); /* * An available vector of the requested priority was found. * Mark it as allocated by clearing the bit. */ --fsb; z_interrupt_vectors_allocated[entry] &= ~BIT(fsb); /* compute vector given allocated bit within the priority level */ vector = (entry << 5) + fsb; return vector; } /** * @brief Get the memory address of an unused dynamic IRQ or exception stub * * We generate at build time a set of dynamic stubs which push * a stub index onto the stack for use as an argument by * common handling code. * * @param stub_idx Stub number to fetch the corresponding stub function * @return Pointer to the stub code to install into the IDT */ __pinned_func static void *get_dynamic_stub(int stub_idx) { uint32_t offset; /* * Because we want the sizes of the stubs to be consistent and minimized, * stubs are grouped into blocks, each containing a push and subsequent * 2-byte jump instruction to the end of the block, which then contains * a larger jump instruction to common dynamic IRQ handling code */ offset = (stub_idx * Z_DYN_STUB_SIZE) + ((stub_idx / Z_DYN_STUB_PER_BLOCK) * Z_DYN_STUB_LONG_JMP_EXTRA_SIZE); return (void *)((uint32_t)&z_dynamic_stubs_begin + offset); } extern const struct pseudo_descriptor z_x86_idt; static void idt_vector_install(int vector, void *irq_handler) { unsigned int key; key = irq_lock(); z_init_irq_gate(&z_x86_idt.entries[vector], CODE_SEG, (uint32_t)irq_handler, 0); irq_unlock(key); } int arch_irq_connect_dynamic(unsigned int irq, unsigned int priority, void (*routine)(const void *parameter), const void *parameter, uint32_t flags) { int vector, stub_idx, key; key = irq_lock(); vector = priority_to_free_vector(priority); /* 0 indicates not used, vectors for interrupts start at 32 */ __ASSERT(_irq_to_interrupt_vector[irq] == 0U, "IRQ %d already configured", irq); _irq_to_interrupt_vector[irq] = vector; z_irq_controller_irq_config(vector, irq, flags); stub_idx = next_irq_stub++; __ASSERT(stub_idx < CONFIG_X86_DYNAMIC_IRQ_STUBS, "No available interrupt stubs found"); dyn_irq_list[stub_idx].handler = routine; dyn_irq_list[stub_idx].param = parameter; idt_vector_install(vector, get_dynamic_stub(stub_idx)); irq_unlock(key); return vector; } /** * @brief Common dynamic IRQ handler function * * This gets called by the IRQ entry asm code with the stub index supplied as * an argument. Look up the required information in dyn_irq_list and * execute it. * * @param stub_idx Index into the dyn_irq_list array */ __pinned_func void z_x86_dynamic_irq_handler(uint8_t stub_idx) { dyn_irq_list[stub_idx].handler(dyn_irq_list[stub_idx].param); } #endif /* CONFIG_X86_DYNAMIC_IRQ_STUBS > 0 */