/* * SPDX-FileCopyrightText: 2021 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Apache-2.0 */ /* Default entry point */ ENTRY(call_start_cpu0); _diram_i_start = 0x40378000; SECTIONS { /** * RTC fast memory holds RTC wake stub code, * including from any source file named rtc_wake_stub*.c */ .rtc.text : { . = ALIGN(4); _rtc_fast_start = ABSOLUTE(.); _rtc_text_start = ABSOLUTE(.); *(.rtc.entry.text) mapping[rtc_text] *rtc_wake_stub*.*(.literal .text .literal.* .text.*) *(.rtc_text_end_test) /* 16B padding for possible CPU prefetch and 4B alignment for PMS split lines */ . += _esp_memprot_prefetch_pad_size; . = ALIGN(4); _rtc_text_end = ABSOLUTE(.); } > rtc_iram_seg /** * This section located in RTC FAST Memory area. * It holds data marked with RTC_FAST_ATTR attribute. * See the file "esp_attr.h" for more information. */ .rtc.force_fast : { . = ALIGN(4); _rtc_force_fast_start = ABSOLUTE(.); mapping[rtc_force_fast] *(.rtc.force_fast .rtc.force_fast.*) . = ALIGN(4) ; _rtc_force_fast_end = ABSOLUTE(.); } > rtc_data_seg /** * RTC data section holds RTC wake stub * data/rodata, including from any source file * named rtc_wake_stub*.c and the data marked with * RTC_DATA_ATTR, RTC_RODATA_ATTR attributes. * The memory location of the data is dependent on * CONFIG_ESP32S3_RTCDATA_IN_FAST_MEM option. */ .rtc.data : { _rtc_data_start = ABSOLUTE(.); mapping[rtc_data] *rtc_wake_stub*.*(.data .rodata .data.* .rodata.*) _rtc_data_end = ABSOLUTE(.); } > rtc_data_location /* RTC bss, from any source file named rtc_wake_stub*.c */ .rtc.bss (NOLOAD) : { _rtc_bss_start = ABSOLUTE(.); *rtc_wake_stub*.*(.bss .bss.*) *rtc_wake_stub*.*(COMMON) mapping[rtc_bss] _rtc_bss_end = ABSOLUTE(.); } > rtc_data_location /** * This section holds data that should not be initialized at power up * and will be retained during deep sleep. * User data marked with RTC_NOINIT_ATTR will be placed * into this section. See the file "esp_attr.h" for more information. * The memory location of the data is dependent on CONFIG_ESP32S3_RTCDATA_IN_FAST_MEM option. */ .rtc_noinit (NOLOAD): { . = ALIGN(4); _rtc_noinit_start = ABSOLUTE(.); *(.rtc_noinit .rtc_noinit.*) . = ALIGN(4) ; _rtc_noinit_end = ABSOLUTE(.); } > rtc_data_location /** * This section located in RTC SLOW Memory area. * It holds data marked with RTC_SLOW_ATTR attribute. * See the file "esp_attr.h" for more information. */ .rtc.force_slow : { . = ALIGN(4); _rtc_force_slow_start = ABSOLUTE(.); *(.rtc.force_slow .rtc.force_slow.*) . = ALIGN(4) ; _rtc_force_slow_end = ABSOLUTE(.); } > rtc_slow_seg /* Get size of rtc slow data based on rtc_data_location alias */ _rtc_slow_length = (ORIGIN(rtc_slow_seg) == ORIGIN(rtc_data_location)) ? (_rtc_force_slow_end - _rtc_data_start) : (_rtc_force_slow_end - _rtc_force_slow_start); _rtc_fast_length = (ORIGIN(rtc_slow_seg) == ORIGIN(rtc_data_location)) ? (_rtc_force_fast_end - _rtc_fast_start) : (_rtc_noinit_end - _rtc_fast_start); ASSERT((_rtc_slow_length <= LENGTH(rtc_slow_seg)), "RTC_SLOW segment data does not fit.") ASSERT((_rtc_fast_length <= LENGTH(rtc_data_seg)), "RTC_FAST segment data does not fit.") /* Send .iram0 code to iram */ .iram0.vectors : { _iram_start = ABSOLUTE(.); /* Vectors go to IRAM */ _vector_table = ABSOLUTE(.); . = 0x0; KEEP(*(.WindowVectors.text)); . = 0x180; KEEP(*(.Level2InterruptVector.text)); . = 0x1c0; KEEP(*(.Level3InterruptVector.text)); . = 0x200; KEEP(*(.Level4InterruptVector.text)); . = 0x240; KEEP(*(.Level5InterruptVector.text)); . = 0x280; KEEP(*(.DebugExceptionVector.text)); . = 0x2c0; KEEP(*(.NMIExceptionVector.text)); . = 0x300; KEEP(*(.KernelExceptionVector.text)); . = 0x340; KEEP(*(.UserExceptionVector.text)); . = 0x3C0; KEEP(*(.DoubleExceptionVector.text)); . = 0x400; _invalid_pc_placeholder = ABSOLUTE(.); *(.*Vector.literal) *(.UserEnter.literal); *(.UserEnter.text); . = ALIGN (16); *(.entry.text) *(.init.literal) *(.init) _init_end = ABSOLUTE(.); } > iram0_0_seg .iram0.text : { /* Code marked as running out of IRAM */ _iram_text_start = ABSOLUTE(.); mapping[iram0_text] } > iram0_0_seg /** * This section is required to skip .iram0.text area because iram0_0_seg and * dram0_0_seg reflect the same address space on different buses. */ .dram0.dummy (NOLOAD): { . = ORIGIN(dram0_0_seg) + MAX(_iram_end - _diram_i_start, 0); } > dram0_0_seg .dram0.data : { _data_start = ABSOLUTE(.); *(.gnu.linkonce.d.*) *(.data1) *(.sdata) *(.sdata.*) *(.gnu.linkonce.s.*) *(.gnu.linkonce.s2.*) *(.jcr) mapping[dram0_data] _data_end = ABSOLUTE(.); . = ALIGN(4); } > dram0_0_seg /** * This section holds data that should not be initialized at power up. * The section located in Internal SRAM memory region. The macro _NOINIT * can be used as attribute to place data into this section. * See the "esp_attr.h" file for more information. */ .noinit (NOLOAD): { . = ALIGN(4); _noinit_start = ABSOLUTE(.); *(.noinit .noinit.*) . = ALIGN(4) ; _noinit_end = ABSOLUTE(.); } > dram0_0_seg /* Shared RAM */ .dram0.bss (NOLOAD) : { . = ALIGN (8); _bss_start = ABSOLUTE(.); mapping[dram0_bss] *(.dynsbss) *(.sbss) *(.sbss.*) *(.gnu.linkonce.sb.*) *(.scommon) *(.sbss2) *(.sbss2.*) *(.gnu.linkonce.sb2.*) *(.dynbss) *(.share.mem) *(.gnu.linkonce.b.*) . = ALIGN (8); _bss_end = ABSOLUTE(.); } > dram0_0_seg ASSERT(((_bss_end - ORIGIN(dram0_0_seg)) <= LENGTH(dram0_0_seg)), "DRAM segment data does not fit.") .flash.text : { _stext = .; _instruction_reserved_start = ABSOLUTE(.); /* This is a symbol marking the flash.text start, this can be used for mmu driver to maintain virtual address */ _text_start = ABSOLUTE(.); mapping[flash_text] *(.stub .gnu.warning .gnu.linkonce.literal.* .gnu.linkonce.t.*.literal .gnu.linkonce.t.*) *(.irom0.text) /* catch stray ICACHE_RODATA_ATTR */ *(.fini.literal) *(.fini) *(.gnu.version) /** CPU will try to prefetch up to 16 bytes of * of instructions. This means that any configuration (e.g. MMU, PMS) must allow * safe access to up to 16 bytes after the last real instruction, add * dummy bytes to ensure this */ . += _esp_flash_mmap_prefetch_pad_size; _text_end = ABSOLUTE(.); _instruction_reserved_end = ABSOLUTE(.); /* This is a symbol marking the flash.text end, this can be used for mmu driver to maintain virtual address */ _etext = .; /** * Similar to _iram_start, this symbol goes here so it is * resolved by addr2line in preference to the first symbol in * the flash.text segment. */ _flash_cache_start = ABSOLUTE(0); } > default_code_seg /** * This dummy section represents the .flash.text section but in default_rodata_seg. * Thus, it must have its alignment and (at least) its size. */ .flash_rodata_dummy (NOLOAD): { _flash_rodata_dummy_start = ABSOLUTE(.); /* Start at the same alignment constraint than .flash.text */ . = ALIGN(ALIGNOF(.flash.text)); /* Create an empty gap as big as .flash.text section */ . = . + SIZEOF(.flash.text); /* Prepare the alignment of the section above. Few bytes (0x20) must be * added for the mapping header. */ . = ALIGN(_esp_mmu_block_size) + 0x20; } > default_rodata_seg .flash.appdesc : ALIGN(0x10) { _rodata_reserved_start = ABSOLUTE(.); /* This is a symbol marking the flash.rodata start, this can be used for mmu driver to maintain virtual address */ _rodata_start = ABSOLUTE(.); *(.rodata_desc .rodata_desc.*) /* Should be the first. App version info. DO NOT PUT ANYTHING BEFORE IT! */ *(.rodata_custom_desc .rodata_custom_desc.*) /* Should be the second. Custom app version info. DO NOT PUT ANYTHING BEFORE IT! */ /* Create an empty gap within this section. Thanks to this, the end of this * section will match .flah.rodata's begin address. Thus, both sections * will be merged when creating the final bin image. */ . = ALIGN(ALIGNOF(.flash.rodata)); } >default_rodata_seg .flash.rodata : ALIGN(0x10) { _flash_rodata_start = ABSOLUTE(.); mapping[flash_rodata] *(.irom1.text) /* catch stray ICACHE_RODATA_ATTR */ *(.gnu.linkonce.r.*) *(.rodata1) __XT_EXCEPTION_TABLE_ = ABSOLUTE(.); *(.xt_except_table) *(.gcc_except_table .gcc_except_table.*) *(.gnu.linkonce.e.*) *(.gnu.version_r) . = (. + 3) & ~ 3; __eh_frame = ABSOLUTE(.); KEEP(*(.eh_frame)) . = (. + 7) & ~ 3; /* C++ constructor and destructor tables */ /* Don't include anything from crtbegin.o or crtend.o, as IDF doesn't use toolchain crt */ __init_array_start = ABSOLUTE(.); KEEP (*(EXCLUDE_FILE (*crtend.* *crtbegin.*) .ctors SORT(.ctors.*))) __init_array_end = ABSOLUTE(.); KEEP (*crtbegin.*(.dtors)) KEEP (*(EXCLUDE_FILE (*crtend.*) .dtors)) KEEP (*(SORT(.dtors.*))) KEEP (*(.dtors)) /* C++ exception handlers table: */ __XT_EXCEPTION_DESCS_ = ABSOLUTE(.); *(.xt_except_desc) *(.gnu.linkonce.h.*) __XT_EXCEPTION_DESCS_END__ = ABSOLUTE(.); *(.xt_except_desc_end) *(.dynamic) *(.gnu.version_d) /* Addresses of memory regions reserved via SOC_RESERVE_MEMORY_REGION() */ soc_reserved_memory_region_start = ABSOLUTE(.); KEEP (*(.reserved_memory_address)) soc_reserved_memory_region_end = ABSOLUTE(.); /* System init functions registered via ESP_SYSTEM_INIT_FN */ _esp_system_init_fn_array_start = ABSOLUTE(.); KEEP (*(SORT_BY_INIT_PRIORITY(.esp_system_init_fn.*))) _esp_system_init_fn_array_end = ABSOLUTE(.); _rodata_end = ABSOLUTE(.); /* Literals are also RO data. */ _lit4_start = ABSOLUTE(.); *(*.lit4) *(.lit4.*) *(.gnu.linkonce.lit4.*) _lit4_end = ABSOLUTE(.); . = ALIGN(4); _thread_local_start = ABSOLUTE(.); *(.tdata) *(.tdata.*) *(.tbss) *(.tbss.*) _thread_local_end = ABSOLUTE(.); . = ALIGN(4); } > default_rodata_seg _flash_rodata_align = ALIGNOF(.flash.rodata); /* This section is a place where we dump all the rodata which aren't used at runtime, so as to avoid binary size increase */ .flash.rodata_noload (NOLOAD) : { /* This is a symbol marking the flash.rodata end, this can be used for mmu driver to maintain virtual address We don't need to include the noload rodata in this section */ _rodata_reserved_end = ABSOLUTE(.); . = ALIGN (4); mapping[rodata_noload] } > default_rodata_seg /** * This section is required to skip flash rodata sections, because `extern_ram_seg` * and `drom0_0_seg` are on the same bus */ .ext_ram.dummy (NOLOAD): { . = ORIGIN(extern_ram_seg) + (_rodata_reserved_end - _flash_rodata_dummy_start); . = ALIGN (0x10000); } > extern_ram_seg /* This section holds .ext_ram.bss data, and will be put in PSRAM */ .ext_ram.bss (NOLOAD) : { _ext_ram_bss_start = ABSOLUTE(.); mapping[extern_ram] . = ALIGN(4); _ext_ram_bss_end = ABSOLUTE(.); } > extern_ram_seg /* Marks the end of IRAM code segment */ .iram0.text_end (NOLOAD) : { /* iram_end_test section exists for use by memprot unit tests only */ *(.iram_end_test) /* ESP32-S3 memprot requires 16B padding for possible CPU prefetch and 256B alignment for PMS split lines */ . += _esp_memprot_prefetch_pad_size; . = ALIGN(_esp_memprot_align_size); _iram_text_end = ABSOLUTE(.); } > iram0_0_seg .iram0.data : { . = ALIGN(4); _iram_data_start = ABSOLUTE(.); mapping[iram0_data] _iram_data_end = ABSOLUTE(.); } > iram0_0_seg .iram0.bss (NOLOAD) : { . = ALIGN(4); _iram_bss_start = ABSOLUTE(.); mapping[iram0_bss] _iram_bss_end = ABSOLUTE(.); . = ALIGN(4); _iram_end = ABSOLUTE(.); } > iram0_0_seg /* Marks the end of data, bss and possibly rodata */ .dram0.heap_start (NOLOAD) : { . = ALIGN (8); _heap_start = ABSOLUTE(.); } > dram0_0_seg /** This section will be used by the debugger and disassembler to get more information * about raw data present in the code. * Indeed, it may be required to add some padding at some points in the code * in order to align a branch/jump destination on a particular bound. * Padding these instructions will generate null bytes that shall be * interpreted as data, and not code by the debugger or disassembler. * This section will only be present in the ELF file, not in the final binary * For more details, check GCC-212 */ .xt.prop 0 : { KEEP (*(.xt.prop .gnu.linkonce.prop.*)) } .xt.lit 0 : { KEEP (*(.xt.lit .gnu.linkonce.p.*)) } } ASSERT(((_iram_end - ORIGIN(iram0_0_seg)) <= LENGTH(iram0_0_seg)), "IRAM0 segment data does not fit.") ASSERT(((_heap_start - ORIGIN(dram0_0_seg)) <= LENGTH(dram0_0_seg)), "DRAM segment data does not fit.")