/* * Copyright (c) 2012-2018 LK Trusty Authors. All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files * (the "Software"), to deal in the Software without restriction, * including without limitation the rights to use, copy, modify, merge, * publish, distribute, sublicense, and/or sell copies of the Software, * and to permit persons to whom the Software is furnished to do so, * subject to the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #include #include #include #include #if WITH_LIB_SM #include #endif #include static spin_lock_t intr_reg_lock; struct int_handler_struct int_handler_table[INT_VECTORS]; /* * IRQ0 to IRQ7 in Master PIC are tranditionally mapped by the BIOS to * interrupts 8 to 15 (0x08 to 0x0F). However, interrupts from 0x0 to * 0x1f are reseverd for exceptions by Intel x86 architecture. In order * to distinguish exception and external interrupts, it is recommended * to change ths PIC's offset so that IRQs are mapped to un-reserved * interrupts vectors. */ static void remap_pic(void) { /* Send ICW1 */ outp(PIC1, ICW1); outp(PIC2, ICW1); /* Send ICW2 to remap */ outp(PIC1 + 1, PIC1_BASE_INTR); outp(PIC2 + 1, PIC2_BASE_INTR); /* Send ICW3 */ outp(PIC1 + 1, ICW3_PIC1); outp(PIC2 + 1, ICW3_PIC2); /* Send ICW4 */ outp(PIC1 + 1, ICW4); outp(PIC2 + 1, ICW4); } /* * PIT is connected to IRQ0 of PIC as hardware timer resource. Trusty Intel * architecture reference utilizes interrupt triggered by PIT as timer * interrupt. To other PIC's IRQs, mask them directly, since Local APIC is * used to handle all other interrupts except timer interrupt. */ static void mask_all_except_irq0(void) { /* Mask all other IRQs except IRQ0(PIT) */ outp(PIC1 + 1, 0xfe); outp(PIC2 + 1, 0xff); } /* * Mask all IRQs of PIC, since Trusty should not receive any external interrupts * from PIC in Android/Trusty solution. */ static void mask_all_irqs(void) { /* Mask all other IRQs except IRQ0(PIT) */ outp(PIC1 + 1, 0xff); outp(PIC2 + 1, 0xff); } void x86_init_interrupts(void) { /* Remap PIC1 IRQ0 to PIC1_BASE_INTR and PIC2 to PIC2_BASE_INTR */ remap_pic(); mask_all_irqs(); /* PIC2 interrupts are cascaded through PIC1 and must be unmasked there */ unmask_interrupt(PIC2_CASCADE_INTR); } static void pic_set_mask(unsigned int vector, bool masked) { uint16_t port; uint line; DEBUG_ASSERT(vector >= PIC1_BASE_INTR); DEBUG_ASSERT(vector < AFTER_PIC_INTR); if (vector < PIC2_BASE_INTR) { port = PIC1 + 1; line = vector - PIC1_BASE_INTR; } else { port = PIC2 + 1; line = vector - PIC2_BASE_INTR; } spin_lock_saved_state_t state; spin_lock_irqsave(&intr_reg_lock, state); uint8_t line_mask = 1U << line; uint8_t current_mask = inp(port); if (masked) { current_mask |= line_mask; } else { current_mask &= ~line_mask; } dprintf(INFO, "new pic mask 0x%x: 0x%x\n", port, current_mask); outp(port, current_mask); spin_unlock_irqrestore(&intr_reg_lock, state); } status_t mask_interrupt(unsigned int vector) { if (vector >= INT_VECTORS) { return ERR_INVALID_ARGS; } if (vector >= PIC1_BASE_INTR && vector < AFTER_PIC_INTR) { pic_set_mask(vector, true); } else { return ERR_NOT_IMPLEMENTED; } return NO_ERROR; } void platform_mask_irqs(void) {} status_t unmask_interrupt(unsigned int vector) { if (vector >= INT_VECTORS) { return ERR_INVALID_ARGS; } if (vector >= PIC1_BASE_INTR && vector < AFTER_PIC_INTR) { pic_set_mask(vector, false); } else { return ERR_NOT_IMPLEMENTED; } return NO_ERROR; } enum handler_return default_isr(unsigned int vector) { enum handler_return ret = INT_NO_RESCHEDULE; #if WITH_LIB_SM /* * Deliver this interrupt to Non-Secure world. At this point, * both Secure and Non-Secure world are all interrupt disabled * after triggering self IPI. This IPI would be acknowledged at * Non-Secure world after world switch. */ send_self_ipi(vector); ret = sm_handle_irq(); #endif lapic_eoi(); return ret; } enum handler_return platform_irq(x86_iframe_t* frame) { /* Get current vector. */ unsigned int vector = frame->vector; enum handler_return ret = INT_NO_RESCHEDULE; int_handler handler = NULL; void* arg = NULL; spin_lock_saved_state_t state; THREAD_STATS_INC(interrupts); spin_lock_irqsave(&intr_reg_lock, state); handler = int_handler_table[vector].handler; arg = int_handler_table[vector].arg; spin_unlock_irqrestore(&intr_reg_lock, state); if (NULL != handler) { ret = handler(arg); if (vector >= PIC1_BASE_INTR && vector < AFTER_PIC_INTR) { if (vector >= PIC2_BASE_INTR) { outp(PIC2, PIC_EOI); } outp(PIC1, PIC_EOI); } } else { ret = default_isr(vector); } return ret; } void register_int_handler(unsigned int vector, int_handler handler, void* arg) { if (vector >= INT_VECTORS) { panic("register_int_handler: vector out of range %d\n", vector); } spin_lock_saved_state_t state; spin_lock_irqsave(&intr_reg_lock, state); if (NULL == int_handler_table[vector].handler) { int_handler_table[vector].arg = arg; int_handler_table[vector].handler = handler; mb(); } else { panic("ISR for vector: %d has been already registered!\n", vector); } spin_unlock_irqrestore(&intr_reg_lock, state); } #if WITH_LIB_SM long smc_intc_get_next_irq(struct smc32_args* args) { long vector; for (vector = args->params[0]; vector < INT_VECTORS; vector++) { if (int_handler_table[vector].handler) { return vector; } } return -1; } status_t sm_intc_fiq_enter(void) { return NO_ERROR; } enum handler_return sm_intc_enable_interrupts(void) { return INT_NO_RESCHEDULE; } #endif