/* * Copyright (c) 2015-2016, Freescale Semiconductor, Inc. * Copyright 2016-2019 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #include "fsl_common.h" #define SDK_MEM_MAGIC_NUMBER 12345U typedef struct _mem_align_control_block { uint16_t identifier; /*!< Identifier for the memory control block. */ uint16_t offset; /*!< offset from aligned address to real address */ } mem_align_cb_t; /* Component ID definition, used by tools. */ #ifndef FSL_COMPONENT_ID #define FSL_COMPONENT_ID "platform.drivers.common" #endif #ifndef __GIC_PRIO_BITS #if defined(ENABLE_RAM_VECTOR_TABLE) uint32_t InstallIRQHandler(IRQn_Type irq, uint32_t irqHandler) { /* Addresses for VECTOR_TABLE and VECTOR_RAM come from the linker file */ #if defined(__CC_ARM) || defined(__ARMCC_VERSION) extern uint32_t Image$$VECTOR_ROM$$Base[]; extern uint32_t Image$$VECTOR_RAM$$Base[]; extern uint32_t Image$$RW_m_data$$Base[]; #define __VECTOR_TABLE Image$$VECTOR_ROM$$Base #define __VECTOR_RAM Image$$VECTOR_RAM$$Base #define __RAM_VECTOR_TABLE_SIZE (((uint32_t)Image$$RW_m_data$$Base - (uint32_t)Image$$VECTOR_RAM$$Base)) #elif defined(__ICCARM__) extern uint32_t __RAM_VECTOR_TABLE_SIZE[]; extern uint32_t __VECTOR_TABLE[]; extern uint32_t __VECTOR_RAM[]; #elif defined(__GNUC__) extern uint32_t __VECTOR_TABLE[]; extern uint32_t __VECTOR_RAM[]; extern uint32_t __RAM_VECTOR_TABLE_SIZE_BYTES[]; uint32_t __RAM_VECTOR_TABLE_SIZE = (uint32_t)(__RAM_VECTOR_TABLE_SIZE_BYTES); #endif /* defined(__CC_ARM) || defined(__ARMCC_VERSION) */ uint32_t n; uint32_t ret; uint32_t irqMaskValue; irqMaskValue = DisableGlobalIRQ(); if (SCB->VTOR != (uint32_t)__VECTOR_RAM) { /* Copy the vector table from ROM to RAM */ for (n = 0; n < ((uint32_t)__RAM_VECTOR_TABLE_SIZE) / sizeof(uint32_t); n++) { __VECTOR_RAM[n] = __VECTOR_TABLE[n]; } /* Point the VTOR to the position of vector table */ SCB->VTOR = (uint32_t)__VECTOR_RAM; } ret = __VECTOR_RAM[irq + 16]; /* make sure the __VECTOR_RAM is noncachable */ __VECTOR_RAM[irq + 16] = irqHandler; EnableGlobalIRQ(irqMaskValue); SDK_ISR_EXIT_BARRIER; return ret; } #endif /* ENABLE_RAM_VECTOR_TABLE. */ #endif /* __GIC_PRIO_BITS. */ #if (defined(FSL_FEATURE_SOC_SYSCON_COUNT) && (FSL_FEATURE_SOC_SYSCON_COUNT > 0)) #if !(defined(FSL_FEATURE_SYSCON_STARTER_DISCONTINUOUS) && FSL_FEATURE_SYSCON_STARTER_DISCONTINUOUS) void EnableDeepSleepIRQ(IRQn_Type interrupt) { uint32_t intNumber = (uint32_t)interrupt; uint32_t index = 0; while (intNumber >= 32u) { index++; intNumber -= 32u; } SYSCON->STARTERSET[index] = 1u << intNumber; EnableIRQ(interrupt); /* also enable interrupt at NVIC */ } void DisableDeepSleepIRQ(IRQn_Type interrupt) { uint32_t intNumber = (uint32_t)interrupt; DisableIRQ(interrupt); /* also disable interrupt at NVIC */ uint32_t index = 0; while (intNumber >= 32u) { index++; intNumber -= 32u; } SYSCON->STARTERCLR[index] = 1u << intNumber; } #endif /* FSL_FEATURE_SYSCON_STARTER_DISCONTINUOUS */ #endif /* FSL_FEATURE_SOC_SYSCON_COUNT */ void *SDK_Malloc(size_t size, size_t alignbytes) { mem_align_cb_t *p_cb = NULL; uint32_t alignedsize = SDK_SIZEALIGN(size, alignbytes) + alignbytes + sizeof(mem_align_cb_t); union { void *pointer_value; uint32_t unsigned_value; } p_align_addr, p_addr; p_addr.pointer_value = malloc(alignedsize); if (p_addr.pointer_value == NULL) { return NULL; } p_align_addr.unsigned_value = SDK_SIZEALIGN(p_addr.unsigned_value + sizeof(mem_align_cb_t), alignbytes); p_cb = (mem_align_cb_t *)(p_align_addr.unsigned_value - 4U); p_cb->identifier = SDK_MEM_MAGIC_NUMBER; p_cb->offset = (uint16_t)(p_align_addr.unsigned_value - p_addr.unsigned_value); return p_align_addr.pointer_value; } void SDK_Free(void *ptr) { union { void *pointer_value; uint32_t unsigned_value; } p_free; p_free.pointer_value = ptr; mem_align_cb_t *p_cb = (mem_align_cb_t *)(p_free.unsigned_value - 4U); if (p_cb->identifier != SDK_MEM_MAGIC_NUMBER) { return; } p_free.unsigned_value = p_free.unsigned_value - p_cb->offset; free(p_free.pointer_value); } /*! * @brief Delay function bases on while loop, every loop includes three instructions. * * @param count Counts of loop needed for dalay. */ #if defined(SDK_DELAY_USE_DWT) && defined(DWT) void enableCpuCycleCounter(void) { /* Make sure the DWT trace fucntion is enabled. */ if (CoreDebug_DEMCR_TRCENA_Msk != (CoreDebug_DEMCR_TRCENA_Msk & CoreDebug->DEMCR)) { CoreDebug->DEMCR |= CoreDebug_DEMCR_TRCENA_Msk; } /* CYCCNT not supported on this device. */ assert(DWT_CTRL_NOCYCCNT_Msk != (DWT->CTRL & DWT_CTRL_NOCYCCNT_Msk)); /* Read CYCCNT directly if CYCCENT has already been enabled, otherwise enable CYCCENT first. */ if (DWT_CTRL_CYCCNTENA_Msk != (DWT_CTRL_CYCCNTENA_Msk & DWT->CTRL)) { DWT->CTRL |= DWT_CTRL_CYCCNTENA_Msk; } } uint32_t getCpuCycleCount(void) { return DWT->CYCCNT; } #elif defined __XCC__ extern uint32_t xthal_get_ccount(void); void enableCpuCycleCounter(void) { /* do nothing */ } uint32_t getCpuCycleCount(void) { return xthal_get_ccount(); } #endif #ifndef __XCC__ #if (!defined(SDK_DELAY_USE_DWT)) || (!defined(DWT)) #if defined(__CC_ARM) /* This macro is arm v5 specific */ /* clang-format off */ __ASM static void DelayLoop(uint32_t count) { loop SUBS R0, R0, #1 CMP R0, #0 BNE loop BX LR } /* clang-format on */ #elif defined(__ARMCC_VERSION) || defined(__ICCARM__) || defined(__GNUC__) /* Cortex-M0 has a smaller instruction set, SUBS isn't supported in thumb-16 mode reported from __GNUC__ compiler, * use SUB and CMP here for compatibility */ static void DelayLoop(uint32_t count) { __ASM volatile(" MOV R0, %0" : : "r"(count)); __ASM volatile( "loop: \n" #if defined(__GNUC__) && !defined(__ARMCC_VERSION) " SUB R0, R0, #1 \n" #else " SUBS R0, R0, #1 \n" #endif " CMP R0, #0 \n" " BNE loop \n"); } #endif /* defined(__CC_ARM) */ #endif /* (!defined(SDK_DELAY_USE_DWT)) || (!defined(DWT)) */ #endif /* __XCC__ */ /*! * @brief Delay at least for some time. * Please note that, if not uses DWT, this API will use while loop for delay, different run-time environments have * effect on the delay time. If precise delay is needed, please enable DWT delay. The two parmeters delay_us and * coreClock_Hz have limitation. For example, in the platform with 1GHz coreClock_Hz, the delay_us only supports * up to 4294967 in current code. If long time delay is needed, please implement a new delay function. * * @param delay_us Delay time in unit of microsecond. * @param coreClock_Hz Core clock frequency with Hz. */ void SDK_DelayAtLeastUs(uint32_t delay_us, uint32_t coreClock_Hz) { assert(0U != delay_us); uint64_t count = USEC_TO_COUNT(delay_us, coreClock_Hz); assert(count <= UINT32_MAX); #if defined(SDK_DELAY_USE_DWT) && defined(DWT) || (defined __XCC__) /* Use DWT for better accuracy */ enableCpuCycleCounter(); /* Calculate the count ticks. */ count += getCpuCycleCount(); if (count > UINT32_MAX) { count -= UINT32_MAX; /* Wait for cyccnt overflow. */ while (count < getCpuCycleCount()) { } } /* Wait for cyccnt reach count value. */ while (count > getCpuCycleCount()) { } #else /* Divide value may be different in various environment to ensure delay is precise. * Every loop count includes three instructions, due to Cortex-M7 sometimes executes * two instructions in one period, through test here set divide 1.5. Other M cores use * divide 4. By the way, divide 1.5 or 4 could let the count lose precision, but it does * not matter because other instructions outside while loop is enough to fill the time. */ #if (__CORTEX_M == 7) count = count / 3U * 2U; #else count = count / 4U; #endif DelayLoop((uint32_t)count); #endif /* defined(SDK_DELAY_USE_DWT) && defined(DWT) || (defined __XCC__) */ }