walnux/boards/arm/rp23xx/raspberrypi-pico-2/scripts/memmap_copy_to_ram.ld

/****************************************************************************
 * boards/arm/rp23xx/raspberrypi-pico-2/scripts/memmap_copy_to_ram.ld
 *
 * SPDX-License-Identifier: Apache-2.0
 *
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.  The
 * ASF licenses this file to you under the Apache License, Version 2.0 (the
 * "License"); you may not use this file except in compliance with the
 * License.  You may obtain a copy of the License at
 *
 *   http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
 * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.  See the
 * License for the specific language governing permissions and limitations
 * under the License.
 *
 ****************************************************************************/

/* Based on GCC ARM embedded samples.
   Defines the following symbols for use by code:
    __exidx_start
    __exidx_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 (== StackTop)
*/

MEMORY
{
    FLASH(rx) : ORIGIN = 0x10000000, LENGTH = 4096k
    RAM(rwx) : ORIGIN =  0x20000000, LENGTH = 512k
    SCRATCH_X(rwx) : ORIGIN = 0x20080000, LENGTH = 4k
    SCRATCH_Y(rwx) : ORIGIN = 0x20081000, LENGTH = 4k
}

ENTRY(_entry_point)

SECTIONS
{
    /* Second stage bootloader is prepended to the image. It must be 256 bytes big
       and checksummed. It is usually built by the boot_stage2 target
       in the Raspberry Pi Pico SDK
    */

    .flash_begin : {
        __flash_binary_start = .;
    } > FLASH

    /* The bootrom will enter the image at the point indicated in your
       IMAGE_DEF, which is usually the reset handler of your vector table.

       The debugger will use the ELF entry point, which is the _entry_point
       symbol, and in our case is *different from the bootrom's entry point.*
       This is used to go back through the bootrom on debugger launches only,
       to perform the same initial flash setup that would be performed on a
       cold boot.
    */

    .flashtext : {
        __logical_binary_start = .;
        KEEP (*(.vectors))
        KEEP (*(.binary_info_header))
        __binary_info_header_end = .;
        KEEP (*(.embedded_block))
        __embedded_block_end = .;
        KEEP (*(.reset))
        . = ALIGN(4);
    } > FLASH

    /* Note the boot2 section is optional, and should be discarded if there is
       no reference to it *inside* the binary, as it is not called by the
       bootrom. (The bootrom performs a simple best-effort XIP setup and
       leaves it to the binary to do anything more sophisticated.) However
       there is still a size limit of 256 bytes, to ensure the boot2 can be
       stored in boot RAM.

       Really this is a "XIP setup function" -- the name boot2 is historic and
       refers to its dual-purpose on RP2040, where it also handled vectoring
       from the bootrom into the user image.
    */

    .boot2 : {
        __boot2_start__ = .;
        *(.boot2)
        __boot2_end__ = .;
    } > FLASH

    ASSERT(__boot2_end__ - __boot2_start__ <= 256,
        "ERROR: Pico second stage bootloader must be no more than 256 bytes in size")

    .rodata : {
        /* segments not marked as .flashdata are instead pulled into .data (in RAM) to avoid accidental flash accesses */
        *(SORT_BY_ALIGNMENT(SORT_BY_NAME(.flashdata*)))
        . = ALIGN(4);
    } > FLASH

    .ARM.extab :
    {
        *(.ARM.extab* .gnu.linkonce.armextab.*)
    } > FLASH

    __exidx_start = .;
    .ARM.exidx :
    {
        *(.ARM.exidx* .gnu.linkonce.armexidx.*)
    } > FLASH
    __exidx_end = .;

    /* Machine inspectable binary information */
    . = ALIGN(4);
    __binary_info_start = .;
    .binary_info :
    {
        KEEP(*(.binary_info.keep.*))
        *(.binary_info.*)
    } > FLASH
    __binary_info_end = .;
    . = ALIGN(4);

    /* Vector table goes first in RAM, to avoid large alignment hole */
    .ram_vector_table (NOLOAD): {
        *(.ram_vector_table)
    } > RAM

    .uninitialized_data (NOLOAD): {
        . = ALIGN(4);
        *(.uninitialized_data*)
    } > RAM

    .text : {
        __ram_text_start__ = .;
        *(.init)
        *(.text*)
        *(.fini)
        /* Pull all c'tors into .text */
        *crtbegin.o(.ctors)
        *crtbegin?.o(.ctors)
        *(EXCLUDE_FILE(*crtend?.o *crtend.o) .ctors)
        *(SORT(.ctors.*))
        *(.ctors)
        /* Followed by destructors */
        *crtbegin.o(.dtors)
        *crtbegin?.o(.dtors)
        *(EXCLUDE_FILE(*crtend?.o *crtend.o) .dtors)
        *(SORT(.dtors.*))
        *(.dtors)

        *(.eh_frame*)
        . = ALIGN(4);
        __ram_text_end__ = .;
    } > RAM AT> FLASH
    __ram_text_source__ = LOADADDR(.text);
    . = ALIGN(4);

    .data : {
        __data_start__ = .;
        *(vtable)

        *(.time_critical*)

        . = ALIGN(4);
        *(.rodata*)
        *(.srodata*)
        . = ALIGN(4);

        *(.data*)
        *(.sdata*)

        . = ALIGN(4);
        *(.after_data.*)
        . = ALIGN(4);
        /* preinit data */
        PROVIDE_HIDDEN (__mutex_array_start = .);
        KEEP(*(SORT(.mutex_array.*)))
        KEEP(*(.mutex_array))
        PROVIDE_HIDDEN (__mutex_array_end = .);

        . = ALIGN(4);
        /* preinit data */
        PROVIDE_HIDDEN (__preinit_array_start = .);
        KEEP(*(SORT(.preinit_array.*)))
        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 = .);
        *(SORT(.fini_array.*))
        *(.fini_array)
        PROVIDE_HIDDEN (__fini_array_end = .);

        *(.jcr)
        . = ALIGN(4);
    } > RAM AT> FLASH

    .tdata : {
        . = ALIGN(4);
		*(.tdata .tdata.* .gnu.linkonce.td.*)
        /* All data end */
        __tdata_end = .;
    } > RAM AT> FLASH
    PROVIDE(__data_end__ = .);

    /* __etext is (for backwards compatibility) the name of the .data init source pointer (...) */
    __etext = LOADADDR(.data);

    .tbss (NOLOAD) : {
        . = ALIGN(4);
        __bss_start__ = .;
        __tls_base = .;
        *(.tbss .tbss.* .gnu.linkonce.tb.*)
        *(.tcommon)

        __tls_end = .;
    } > RAM

    .bss  : {
        . = ALIGN(4);
        __tbss_end = .;

        *(SORT_BY_ALIGNMENT(SORT_BY_NAME(.bss*)))
        *(COMMON)
        PROVIDE(__global_pointer$ = . + 2K);
        *(.sbss*)
        . = ALIGN(4);
        __bss_end__ = .;
    } > RAM

    .heap (NOLOAD):
    {
        __end__ = .;
        end = __end__;
        KEEP(*(.heap*))
    } > RAM
        /* historically on GCC sbrk was growing past __HeapLimit to __StackLimit, however
       to be more compatible, we now set __HeapLimit explicitly to where the end of the heap is */
    __HeapLimit = ORIGIN(RAM) + LENGTH(RAM);


    /* Start and end symbols must be word-aligned */
    .scratch_x : {
        __scratch_x_start__ = .;
        *(.scratch_x.*)
        . = ALIGN(4);
        __scratch_x_end__ = .;
    } > SCRATCH_X AT > FLASH
    __scratch_x_source__ = LOADADDR(.scratch_x);

    .scratch_y : {
        __scratch_y_start__ = .;
        *(.scratch_y.*)
        . = ALIGN(4);
        __scratch_y_end__ = .;
    } > SCRATCH_Y AT > FLASH
    __scratch_y_source__ = LOADADDR(.scratch_y);

    /* .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
     *
     * stack1 section may be empty/missing if platform_launch_core1 is not used */

    /* by default we put core 0 stack at the end of scratch Y, so that if core 1
     * stack is not used then all of SCRATCH_X is free.
     */
    .stack1_dummy (NOLOAD):
    {
        *(.stack1*)
    } > SCRATCH_X
    .stack_dummy (NOLOAD):
    {
        KEEP(*(.stack*))
    } > SCRATCH_Y

    .flash_end : {
        KEEP(*(.embedded_end_block*))
        PROVIDE(__flash_binary_end = .);
    } > FLASH =0xaa

    /* stack limit is poorly named, but historically is maximum heap ptr */
    __StackLimit = ORIGIN(RAM) + LENGTH(RAM);
    __StackOneTop = ORIGIN(SCRATCH_X) + LENGTH(SCRATCH_X);
    __StackTop = ORIGIN(SCRATCH_Y) + LENGTH(SCRATCH_Y);
    __StackOneBottom = __StackOneTop - SIZEOF(.stack1_dummy);
    __StackBottom = __StackTop - SIZEOF(.stack_dummy);
    PROVIDE(__stack = __StackTop);

    /* picolibc and LLVM */
    PROVIDE (__heap_start = __end__);
    PROVIDE (__heap_end = __HeapLimit);
    PROVIDE( __tls_align = MAX(ALIGNOF(.tdata), ALIGNOF(.tbss)) );
    PROVIDE( __tls_size_align = (__tls_size + __tls_align - 1) & ~(__tls_align - 1));
    PROVIDE( __arm32_tls_tcb_offset = MAX(8, __tls_align) );

    /* llvm-libc */
    PROVIDE (_end = __end__);
    PROVIDE (__llvm_libc_heap_limit = __HeapLimit);

    /* Check if data + heap + stack exceeds RAM limit */
    ASSERT(__StackLimit >= __HeapLimit, "region RAM overflowed")

    ASSERT( __binary_info_header_end - __logical_binary_start <= 1024, "Binary info must be in first 1024 bytes of the binary")
    ASSERT( __embedded_block_end - __logical_binary_start <= 4096, "Embedded block must be in first 4096 bytes of the binary")

    /* todo assert on extra code */
}