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/* Linker script for the Midas labs RTE-NB85E-CB evaluation board
(CONFIG_RTE_CB_NB85E), with the Multi debugger ROM monitor . */
MEMORY {
/* 1MB of SRAM; we can't use the last 96KB, because it's used by
the monitor scratch-RAM. This memory is mirrored 4 times. */
SRAM : ORIGIN = SRAM_ADDR, LENGTH = (SRAM_SIZE - MON_SCRATCH_SIZE)
/* Monitor scratch RAM; only the interrupt vectors should go here. */
MRAM : ORIGIN = MON_SCRATCH_ADDR, LENGTH = MON_SCRATCH_SIZE
/* 16MB of SDRAM. */
SDRAM : ORIGIN = SDRAM_ADDR, LENGTH = SDRAM_SIZE
}
#ifdef CONFIG_RTE_CB_NB85E_KSRAM
# define KRAM SRAM
#else
# define KRAM SDRAM
#endif
SECTIONS {
/* We can't use RAMK_KRAM_CONTENTS because that puts the whole
kernel in a single ELF segment, and the Multi debugger (which
we use to load the kernel) appears to have bizarre problems
dealing with it. */
.text : {
__kram_start = . ;
TEXT_CONTENTS
} > KRAM
.data : {
DATA_CONTENTS
BSS_CONTENTS
RAMK_INIT_CONTENTS
__kram_end = . ;
BOOTMAP_CONTENTS
/* The address at which the interrupt vectors are initially
loaded by the loader. We can't load the interrupt vectors
directly into their target location, because the monitor
ROM for the GHS Multi debugger barfs if we try.
Unfortunately, Multi also doesn't deal correctly with ELF
sections where the LMA and VMA differ (it just ignores the
LMA), so we can't use that feature to work around the
problem! What we do instead is just put the interrupt
vectors into a normal section, and have the
`mach_early_init' function for Midas boards do the
necessary copying and relocation at runtime (this section
basically only contains `jr' instructions, so it's not
that hard). */
. = ALIGN (0x10) ;
__intv_load_start = . ;
INTV_CONTENTS
} > KRAM
.root ALIGN (4096) : { ROOT_FS_CONTENTS } > SDRAM
}
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