/**************************************************************************************** * @file flash.ld * * @brief This file is the link script file (gnuarm or armgcc). * * Copyright (C) BouffaloLab 2021 * **************************************************************************************** */ /* configure the CPU type */ OUTPUT_ARCH( "riscv" ) /* link with the standard c library */ INPUT(-lc) /* link with the standard GCC library */ INPUT(-lgcc) /* configure the entry point */ ENTRY(__start) StackSize = 0x0400; /* 1KB */ HeapMinSize = 0x1000; /* 4KB */ MEMORY { fw_header_memory0 (rx) : ORIGIN = 0x58020000 - 0x1000, LENGTH = 4K xip_memory (rx) : ORIGIN = 0x58020000, LENGTH = 1M itcm_memory (rx) : ORIGIN = 0x2202C000, LENGTH = 16K dtcm_memory (rx) : ORIGIN = 0x22030000, LENGTH = 16K nocache_ram_memory (!rx) : ORIGIN = 0x22030000, LENGTH = 0K ram_memory (!rx) : ORIGIN = 0x22034000, LENGTH = 16K xram_memory (!rx) : ORIGIN = 0x40000000, LENGTH = 16K } SECTIONS { .fw_header : { KEEP(*(.fw_header)) } > fw_header_memory0 .text : { . = ALIGN(4); __text_code_start__ = .; KEEP (*(SORT_NONE(.init))) KEEP (*(SORT_NONE(.vector))) *(.text) *(.text.*) /* section information for shell */ . = ALIGN(4); __fsymtab_start = .; KEEP(*(FSymTab)) __fsymtab_end = .; . = ALIGN(4); __vsymtab_start = .; KEEP(*(VSymTab)) __vsymtab_end = .; /* section information for usb usbh_class_info */ . = ALIGN(4); __usbh_class_info_start__ = .; KEEP(*(.usbh_class_info)) . = ALIGN(4); __usbh_class_info_end__ = .; /*put .rodata**/ *(EXCLUDE_FILE( *bl808_glb*.o* \ *bl808_glb_gpio*.o* \ *bl808_pds*.o* \ *bl808_aon*.o* \ *bl808_hbn*.o* \ *bl808_l1c*.o* \ *bl808_common*.o* \ *bl808_clock*.o* \ *bl808_ef_ctrl*.o* \ *bl808_sf_cfg*.o* \ *bl808_sf_ctrl*.o* \ *bl808_sflash*.o* \ *bl808_xip_sflash*.o* \ *bl808_romapi_patch*.o* ) .rodata*) *(.srodata) *(.srodata.*) . = ALIGN(4); __text_code_end__ = .; } > xip_memory . = ALIGN(4); __itcm_load_addr = .; .itcm_region : AT (__itcm_load_addr) { . = ALIGN(4); __tcm_code_start__ = .; *(.tcm_code.*) *(.tcm_const.*) *(.sclock_rlt_code.*) *(.sclock_rlt_const.*) *bl808_glb*.o*(.rodata*) *bl808_glb_gpio*.o*(.rodata*) *bl808_pds*.o*(.rodata*) *bl808_aon*.o*(.rodata*) *bl808_hbn*.o*(.rodata*) *bl808_l1c*.o*(.rodata*) *bl808_common*.o*(.rodata*) *bl808_clock*.o*(.rodata*) *bl808_ef_ctrl*.o*(.rodata*) *bl808_sf_cfg*.o*(.rodata*) *bl808_sf_ctrl*.o*(.rodata*) *bl808_sflash*.o*(.rodata*) *bl808_xip_sflash*.o*(.rodata*) *bl808_romapi_patch*.o*(.rodata*) . = ALIGN(4); __tcm_code_end__ = .; } > itcm_memory __dtcm_load_addr = __itcm_load_addr + SIZEOF(.itcm_region); .dtcm_region : AT (__dtcm_load_addr) { . = ALIGN(4); __tcm_data_start__ = .; *(.tcm_data) /* *finger_print.o(.data*) */ . = ALIGN(4); __tcm_data_end__ = .; } > dtcm_memory /*************************************************************************/ /* .stack_dummy section doesn't contains any symbols. It is only * used for linker to calculate size of stack sections, and assign * values to stack symbols later */ .stack_dummy (NOLOAD): { . = ALIGN(0x4); . = . + StackSize; . = ALIGN(0x4); } > dtcm_memory /* Set stack top to end of RAM, and stack limit move down by * size of stack_dummy section */ __StackTop = ORIGIN(dtcm_memory) + LENGTH(dtcm_memory); PROVIDE( __freertos_irq_stack_top = __StackTop); __StackLimit = __StackTop - SIZEOF(.stack_dummy); /* Check if data + heap + stack exceeds RAM limit */ ASSERT(__StackLimit >= __tcm_data_end__, "region RAM overflowed with stack") /*************************************************************************/ __nocache_ram_load_addr = __dtcm_load_addr + SIZEOF(.dtcm_region); .nocache_ram_region : AT (__nocache_ram_load_addr) { . = ALIGN(4); __nocache_ram_data_start__ = .; *(.nocache_ram) . = ALIGN(4); __nocache_ram_data_end__ = .; } > nocache_ram_memory __ram_load_addr = __nocache_ram_load_addr + SIZEOF(.nocache_ram_region); /* Data section */ RAM_DATA : AT (__ram_load_addr) { . = ALIGN(4); __ram_data_start__ = .; PROVIDE( __global_pointer$ = . + 0x800 ); *(.data) *(.data.*) *(.sdata) *(.sdata.*) *(.sdata2) *(.sdata2.*) . = ALIGN(4); __bflog_tags_start__ = .; *(.bflog_tags_array) . = ALIGN(4); __bflog_tags_end__ = .; __ram_data_end__ = .; } > ram_memory __etext_final = (__ram_load_addr + SIZEOF (RAM_DATA)); ASSERT(__etext_final <= ORIGIN(xip_memory) + LENGTH(xip_memory), "code memory overflow") .bss (NOLOAD) : { . = ALIGN(4); __bss_start__ = .; *(.bss*) *(.sbss*) *(COMMON) . = ALIGN(4); __bss_end__ = .; } > ram_memory .noinit_data (NOLOAD) : { . = ALIGN(4); __noinit_data_start__ = .; *(.noinit_data*) . = ALIGN(4); __noinit_data_end__ = .; } > ram_memory .nocache_noinit_ram_region (NOLOAD) : { . = ALIGN(4); __nocache_noinit_ram_data_start__ = .; *(.nocache_noinit_ram) *(.noncacheable) . = ALIGN(4); __nocache_noinit_ram_data_end__ = .; } > nocache_ram_memory .heap (NOLOAD): { . = ALIGN(4); __HeapBase = .; /*__end__ = .;*/ /*end = __end__;*/ KEEP(*(.heap*)) . = ALIGN(4); __HeapLimit = .; } > ram_memory __HeapLimit = ORIGIN(ram_memory) + LENGTH(ram_memory); ASSERT(__HeapLimit - __HeapBase >= HeapMinSize, "heap region overflow") }