circuitpython/ports/renesas-ra/boards/RA4M1_EK/ra4m1_ek.ld
Takeo Takahashi 0f57ccf7f2 renesas-ra: Add new port to Renesas RA.
Signed-off-by: Takeo Takahashi <takeo.takahashi.xv@renesas.com>
2022-04-29 12:29:06 +09:00

299 lines
7.4 KiB
Plaintext

/*
Linker File for RA4M1 MCU
*/
/* Linker script to configure memory regions. */
MEMORY
{
FLASH (rx) : ORIGIN = 0x00000000, LENGTH = 0x00040000 /* 256KB */
RAM (rwx) : ORIGIN = 0x20000000, LENGTH = 0x00008000 /* 32KB */
DATA_FLASH (rx) : ORIGIN = 0x40100000, LENGTH = 0x00002000 /* 8KB */
ID_CODE (rx) : ORIGIN = 0x01010018, LENGTH = 0x00000020 /* 32bytes */
}
/* Library configurations */
/*GROUP(libgcc.a libc.a libm.a libnosys.a) */
/* Linker script to place sections and symbol values. Should be used together
* with other linker script that defines memory regions FLASH and RAM.
* It references following symbols, which must be defined in code:
* Reset_Handler : Entry of reset handler
*
* It defines following symbols, which code can use without definition:
* __exidx_start
* __exidx_end
* __copy_table_start__
* __copy_table_end__
* __zero_table_start__
* __zero_table_end__
* __etext
* __data_start__
* __preinit_array_start
* __preinit_array_end
* __init_array_start
* __init_array_end
* __fini_array_start
* __fini_array_end
* __data_end__
* __bss_start__
* __bss_end__
* __end__
* end
* __HeapLimit
* __StackLimit
* __StackTop
* __stack
* __Vectors_End
* __Vectors_Size
*/
ENTRY(Reset_Handler)
SECTIONS
{
.text :
{
_stext = .;
__ROM_Start = .;
/* Even though the vector table is not 256 entries (1KB) long, we still allocate that much
* space because ROM registers are at address 0x400 and there is very little space
* in between. */
KEEP(*(.fixed_vectors*))
KEEP(*(.application_vectors*))
__Vectors_End = .;
__end__ = .;
/* ROM Registers start at address 0x00000400 */
. = __ROM_Start + 0x400;
KEEP(*(.rom_registers*))
/* Reserving 0x100 bytes of space for ROM registers. */
. = __ROM_Start + 0x500;
*(.text*)
KEEP(*(.version))
KEEP(*(.init))
KEEP(*(.fini))
/* .ctors */
*crtbegin.o(.ctors)
*crtbegin?.o(.ctors)
*(EXCLUDE_FILE(*crtend?.o *crtend.o) .ctors)
*(SORT(.ctors.*))
*(.ctors)
/* .dtors */
*crtbegin.o(.dtors)
*crtbegin?.o(.dtors)
*(EXCLUDE_FILE(*crtend?.o *crtend.o) .dtors)
*(SORT(.dtors.*))
*(.dtors)
*(.rodata*)
__usb_dev_descriptor_start_fs = .;
KEEP(*(.usb_device_desc_fs*))
__usb_cfg_descriptor_start_fs = .;
KEEP(*(.usb_config_desc_fs*))
__usb_interface_descriptor_start_fs = .;
KEEP(*(.usb_interface_desc_fs*))
__usb_descriptor_end_fs = .;
__usb_dev_descriptor_start_hs = .;
KEEP(*(.usb_device_desc_hs*))
__usb_cfg_descriptor_start_hs = .;
KEEP(*(.usb_config_desc_hs*))
__usb_interface_descriptor_start_hs = .;
KEEP(*(.usb_interface_desc_hs*))
__usb_descriptor_end_hs = .;
KEEP(*(.eh_frame*))
__ROM_End = .;
_etext = .;
} > FLASH = 0xFF
__Vectors_Size = __Vectors_End - __Vectors;
.ARM.extab :
{
*(.ARM.extab* .gnu.linkonce.armextab.*)
} > FLASH
__exidx_start = .;
.ARM.exidx :
{
*(.ARM.exidx* .gnu.linkonce.armexidx.*)
} > FLASH
__exidx_end = .;
/* To copy multiple ROM to RAM sections,
* uncomment .copy.table section and,
* define __STARTUP_COPY_MULTIPLE in startup_ARMCMx.S */
/*
.copy.table :
{
. = ALIGN(4);
__copy_table_start__ = .;
LONG (__etext)
LONG (__data_start__)
LONG (__data_end__ - __data_start__)
LONG (__etext2)
LONG (__data2_start__)
LONG (__data2_end__ - __data2_start__)
__copy_table_end__ = .;
} > FLASH
*/
/* To clear multiple BSS sections,
* uncomment .zero.table section and,
* define __STARTUP_CLEAR_BSS_MULTIPLE in startup_ARMCMx.S */
/*
.zero.table :
{
. = ALIGN(4);
__zero_table_start__ = .;
LONG (__bss_start__)
LONG (__bss_end__ - __bss_start__)
LONG (__bss2_start__)
LONG (__bss2_end__ - __bss2_start__)
__zero_table_end__ = .;
} > FLASH
*/
__etext = .;
/* If DTC is used, put the DTC vector table at the start of SRAM.
This avoids memory holes due to 1K alignment required by it. */
.fsp_dtc_vector_table (NOLOAD) :
{
. = ORIGIN(RAM);
*(.fsp_dtc_vector_table)
} > RAM
/* Initialized data section. */
.data :
{
_sidata = .;
_sdata = .;
__data_start__ = .;
*(vtable)
*(.data.*)
. = ALIGN(4);
/* preinit data */
PROVIDE_HIDDEN (__preinit_array_start = .);
KEEP(*(.preinit_array))
PROVIDE_HIDDEN (__preinit_array_end = .);
. = ALIGN(4);
/* init data */
PROVIDE_HIDDEN (__init_array_start = .);
KEEP(*(SORT(.init_array.*)))
KEEP(*(.init_array))
PROVIDE_HIDDEN (__init_array_end = .);
. = ALIGN(4);
/* finit data */
PROVIDE_HIDDEN (__fini_array_start = .);
KEEP(*(SORT(.fini_array.*)))
KEEP(*(.fini_array))
PROVIDE_HIDDEN (__fini_array_end = .);
KEEP(*(.jcr*))
. = ALIGN(4);
__Code_In_RAM_Start = .;
KEEP(*(.code_in_ram*))
__Code_In_RAM_End = .;
/* All data end */
__data_end__ = .;
_edata = .;
} > RAM AT > FLASH
.noinit (NOLOAD):
{
. = ALIGN(4);
__noinit_start = .;
KEEP(*(.noinit*))
__noinit_end = .;
} > RAM
.bss :
{
. = ALIGN(4);
_sbss = .;
__bss_start__ = .;
*(.bss*)
*(COMMON)
. = ALIGN(4);
__bss_end__ = .;
_ebss = .;
} > RAM
.heap (NOLOAD):
{
. = ALIGN(8);
__HeapBase = .;
__end__ = .;
end = __end__;
KEEP(*(.heap*))
__HeapLimit = .;
} > RAM
/* Stacks are stored in this section. */
.stack_dummy (NOLOAD):
{
. = ALIGN(8);
_sstack = .;
__StackLimit = .;
/* Main stack */
KEEP(*(.stack))
__StackTop = .;
/* Thread stacks */
KEEP(*(.stack*))
__StackTopAll = .;
_estack = .;
} > RAM
PROVIDE(__stack = __StackTopAll);
/* This symbol represents the end of user allocated RAM. The RAM after this symbol can be used
at run time for things such as ThreadX memory pool allocations. */
__RAM_segment_used_end__ = ALIGN(__StackTopAll , 4);
/* Data flash. */
.data_flash :
{
__Data_Flash_Start = .;
KEEP(*(.data_flash*))
__Data_Flash_End = .;
} > DATA_FLASH
.id_code :
{
__ID_Code_Start = .;
KEEP(*(.id_code*))
__ID_Code_End = .;
} > ID_CODE
}
/* produce a link error if there is not this amount of RAM for these sections */
/* _minimum_stack_size = 2K; */
/* _minimum_heap_size = 16K; */
/* Define tho top end of the stack. The stack is full descending so begins just
above last byte of RAM. Note that EABI requires the stack to be 8-byte
aligned for a call. */
_estack = ORIGIN(RAM) + LENGTH(RAM);
/* RAM extents for the garbage collector */
_ram_start = ORIGIN(RAM);
_ram_end = ORIGIN(RAM) + LENGTH(RAM);
_heap_start = __HeapBase; /* heap starts just after statically allocated memory */
_heap_end = __HeapLimit; /* tunable */