/* * Copyright (c) 2019 Synopsys. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief ARCv2 ARC CONNECT driver * */ #include #include #include #include static struct k_spinlock arc_connect_spinlock; /* Generate an inter-core interrupt to the target core */ void z_arc_connect_ici_generate(uint32_t core) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_INTRPT_GENERATE_IRQ, core); } } /* Acknowledge the inter-core interrupt raised by core */ void z_arc_connect_ici_ack(uint32_t core) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_INTRPT_GENERATE_ACK, core); } } /* Read inter-core interrupt status */ uint32_t z_arc_connect_ici_read_status(uint32_t core) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_INTRPT_READ_STATUS, core); ret = z_arc_connect_cmd_readback(); } return ret; } /* Check the source of inter-core interrupt */ uint32_t z_arc_connect_ici_check_src(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_INTRPT_CHECK_SOURCE, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Clear the inter-core interrupt */ void z_arc_connect_ici_clear(void) { uint32_t cpu, c; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_INTRPT_CHECK_SOURCE, 0); cpu = z_arc_connect_cmd_readback(); /* 1,2,4,8... */ /* * In rare case, multiple concurrent ICIs sent to same target can * possibly be coalesced by MCIP into 1 asserted IRQ, so @cpu can be * "vectored" (multiple bits sets) as opposed to typical single bit */ while (cpu) { c = find_lsb_set(cpu) - 1; z_arc_connect_cmd( ARC_CONNECT_CMD_INTRPT_GENERATE_ACK, c); cpu &= ~(1U << c); } } } /* Reset the cores in core_mask */ void z_arc_connect_debug_reset(uint32_t core_mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_DEBUG_RESET, 0, core_mask); } } /* Halt the cores in core_mask */ void z_arc_connect_debug_halt(uint32_t core_mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_DEBUG_HALT, 0, core_mask); } } /* Run the cores in core_mask */ void z_arc_connect_debug_run(uint32_t core_mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_DEBUG_RUN, 0, core_mask); } } /* Set core mask */ void z_arc_connect_debug_mask_set(uint32_t core_mask, uint32_t mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_DEBUG_SET_MASK, mask, core_mask); } } /* Read core mask */ uint32_t z_arc_connect_debug_mask_read(uint32_t core_mask) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_DEBUG_READ_MASK, 0, core_mask); ret = z_arc_connect_cmd_readback(); } return ret; } /* * Select cores that should be halted if the core issuing the command is halted */ void z_arc_connect_debug_select_set(uint32_t core_mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_DEBUG_SET_SELECT, 0, core_mask); } } /* Read the select value */ uint32_t z_arc_connect_debug_select_read(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_DEBUG_READ_SELECT, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Read the status, halt or run of all cores in the system */ uint32_t z_arc_connect_debug_en_read(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_DEBUG_READ_EN, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Read the last command sent */ uint32_t z_arc_connect_debug_cmd_read(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_DEBUG_READ_CMD, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Read the value of internal MCD_CORE register */ uint32_t z_arc_connect_debug_core_read(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_DEBUG_READ_CORE, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Clear global free running counter */ void z_arc_connect_gfrc_clear(void) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_CLEAR, 0); } } /* Read total 64 bits of global free running counter */ uint64_t z_arc_connect_gfrc_read(void) { uint32_t low; uint32_t high; uint32_t key; /* * each core has its own arc connect interface, i.e., * CMD/READBACK. So several concurrent commands to ARC * connect are of if they are trying to access different * sub-components. For GFRC, HW allows simultaneously accessing to * counters. So an irq lock is enough. */ key = arch_irq_lock(); z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_READ_LO, 0); low = z_arc_connect_cmd_readback(); z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_READ_HI, 0); high = z_arc_connect_cmd_readback(); arch_irq_unlock(key); return (((uint64_t)high) << 32) | low; } /* Enable global free running counter */ void z_arc_connect_gfrc_enable(void) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_ENABLE, 0); } } /* Disable global free running counter */ void z_arc_connect_gfrc_disable(void) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_DISABLE, 0); } } /* Disable global free running counter */ void z_arc_connect_gfrc_core_set(uint32_t core_mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_GFRC_SET_CORE, 0, core_mask); } } /* Set the relevant cores to halt global free running counter */ uint32_t z_arc_connect_gfrc_halt_read(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_READ_HALT, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Read the internal CORE register */ uint32_t z_arc_connect_gfrc_core_read(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_GFRC_READ_CORE, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* Enable interrupt distribute unit */ void z_arc_connect_idu_enable(void) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_ENABLE, 0); } } /* Disable interrupt distribute unit */ void z_arc_connect_idu_disable(void) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_DISABLE, 0); } } /* Read enable status of interrupt distribute unit */ uint32_t z_arc_connect_idu_read_enable(void) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_READ_ENABLE, 0); ret = z_arc_connect_cmd_readback(); } return ret; } /* * Set the triggering mode and distribution mode for the specified common * interrupt */ void z_arc_connect_idu_set_mode(uint32_t irq_num, uint16_t trigger_mode, uint16_t distri_mode) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_IDU_SET_MODE, irq_num, (distri_mode | (trigger_mode << 4))); } } /* Read the internal MODE register of the specified common interrupt */ uint32_t z_arc_connect_idu_read_mode(uint32_t irq_num) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_READ_MODE, irq_num); ret = z_arc_connect_cmd_readback(); } return ret; } /* * Set the target cores to receive the specified common interrupt * when it is triggered */ void z_arc_connect_idu_set_dest(uint32_t irq_num, uint32_t core_mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_IDU_SET_DEST, irq_num, core_mask); } } /* Read the internal DEST register of the specified common interrupt */ uint32_t z_arc_connect_idu_read_dest(uint32_t irq_num) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_READ_DEST, irq_num); ret = z_arc_connect_cmd_readback(); } return ret; } /* Assert the specified common interrupt */ void z_arc_connect_idu_gen_cirq(uint32_t irq_num) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_GEN_CIRQ, irq_num); } } /* Acknowledge the specified common interrupt */ void z_arc_connect_idu_ack_cirq(uint32_t irq_num) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_ACK_CIRQ, irq_num); } } /* Read the internal STATUS register of the specified common interrupt */ uint32_t z_arc_connect_idu_check_status(uint32_t irq_num) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_CHECK_STATUS, irq_num); ret = z_arc_connect_cmd_readback(); } return ret; } /* Read the internal SOURCE register of the specified common interrupt */ uint32_t z_arc_connect_idu_check_source(uint32_t irq_num) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_CHECK_SOURCE, irq_num); ret = z_arc_connect_cmd_readback(); } return ret; } /* Mask or unmask the specified common interrupt */ void z_arc_connect_idu_set_mask(uint32_t irq_num, uint32_t mask) { K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd_data(ARC_CONNECT_CMD_IDU_SET_MASK, irq_num, mask); } } /* Read the internal MASK register of the specified common interrupt */ uint32_t z_arc_connect_idu_read_mask(uint32_t irq_num) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_READ_MASK, irq_num); ret = z_arc_connect_cmd_readback(); } return ret; } /* * Check if it is the first-acknowledging core to the common interrupt * if IDU is programmed in the first-acknowledged mode */ uint32_t z_arc_connect_idu_check_first(uint32_t irq_num) { uint32_t ret = 0; K_SPINLOCK(&arc_connect_spinlock) { z_arc_connect_cmd(ARC_CONNECT_CMD_IDU_CHECK_FIRST, irq_num); ret = z_arc_connect_cmd_readback(); } return ret; }