#include "config.h" ENTRY(_vectors) OUTPUT_FORMAT(elf32-littlearm) OUTPUT_ARCH(arm) STARTUP(target/arm/tms320dm320/crt0.o) #ifndef LCD_NATIVE_WIDTH #define LCD_NATIVE_WIDTH LCD_WIDTH #endif #ifndef LCD_NATIVE_HEIGHT #define LCD_NATIVE_HEIGHT LCD_HEIGHT #endif #define LCD_FUDGE LCD_NATIVE_WIDTH%32 #define LCD_BUFFER_SIZE ((LCD_NATIVE_WIDTH+LCD_FUDGE)*LCD_NATIVE_HEIGHT*2) /* must be 16Kb (0x4000) aligned */ #define TTB_SIZE (0x4000) /* Give this some memory to allow it to align to the MMU boundary. * Note that since there are two buffers (YUV/RGB) it calculates the approximate * memory needed in steps of 1 Meg. */ #define LCD_TTB_AREA 0x100000*((LCD_BUFFER_SIZE>>19)+1) /* Bootloader only uses/knows about the upper 32 M */ #define DRAMORIG 0x02900000 #define DRAMSIZE (MEMORYSIZE * 0x80000) #define IRAMORIG 0x00000000 #define IRAMSIZE 0x4000 #define FLASHORIG 0x00100000 #define FLASHSIZE 0x00800000 PRO_STACK_SIZE = 0x2000; IRQ_STACK_SIZE = 0x400; FIQ_STACK_SIZE = 0x400; /* End of the audio buffer, where the codec buffer starts */ #define TTB_BEGIN (DRAMORIG + DRAMSIZE - LCD_TTB_AREA) MEMORY { DRAM : ORIGIN = DRAMORIG, LENGTH = DRAMSIZE IRAM : ORIGIN = IRAMORIG, LENGTH = IRAMSIZE FLASH : ORIGIN = FLASHORIG, LENGTH = FLASHSIZE } SECTIONS { /* Set up variables needed for memory initialization */ _sdram_start = DRAMORIG; _sdram_sizem = (DRAMSIZE / 0x100000); _flash_start = FLASHORIG; _flash_sizem = (FLASHSIZE / 0x100000); .vectors : { _vectorsstart = .; KEEP(*(.vectors)) _vectorsend = .; } > IRAM AT> FLASH _vectorscopy = LOADADDR(.vectors); /* crt0.S initialization */ .init : { . = ALIGN(0x4); _loadaddress = .; *(.init) } > FLASH /* Program code */ .text : { . = ALIGN(0x4); *(.text*) } > FLASH /* Thumb interworking sections - for some reason LD dies even if these * sections are empty. */ .glue : { . = ALIGN(0x4); *(.glue_7) /* ARM calling Thumb */ *(.glue_7t) /* Thumb calling ARM */ } > FLASH /* Read-only data */ .rodata : { . = ALIGN(0x4); *(.rodata*) } > FLASH /* Dynamic data - this needs to be copied out of flash before it is used. */ .data : { . = ALIGN(0x4); _dramstart = .; *(.data*) _dramend = .; } > DRAM AT> FLASH _dramcopy = LOADADDR(.data); .bss (NOLOAD) : { . = ALIGN(0x4); _bss_start = .; *(.bss*) *(COMMON) _bss_end = .; } > DRAM .iram : { . = ALIGN(0x4); _iramstart = .; *(.icode) *(.irodata) *(.idata) _iramend = .; } > IRAM AT> FLASH _iramcopy = LOADADDR(.iram); .ibss (NOLOAD) : { . = ALIGN(0x4); _ibss_start = .; *(.ibss) _ibss_end = .; } > IRAM /* Program stack space */ .pro_stack (NOLOAD): { . = ALIGN(0x4); *(.stack) stackbegin = .; /* Variable for thread.c */ _pro_stack_end = .; . += PRO_STACK_SIZE; _pro_stack_start = .; stackend = .; /* Variable for tread.c */ } > IRAM /* IRQ stack space */ .irq_stack (NOLOAD): { . = ALIGN(0x4); _irq_stack_end = .; . += IRQ_STACK_SIZE; _irq_stack_start = .; } > IRAM /* FIQ stack space */ .fiq_stack (NOLOAD): { . = ALIGN(0x4); _fiq_stack_end = .; . += FIQ_STACK_SIZE; _fiq_stack_start = .; } > IRAM .ttbtable TTB_BEGIN (NOLOAD) : { . = ALIGN (0x4000); _ttbstart = .; . += TTB_SIZE; } > DRAM /* The LCD buffer should be at the end of memory to protect against * overflowing something else when the YUV blitter is fudging the screen * size. */ .lcdbuffer (NOLOAD) : { _lcdbuf = .; . += LCD_BUFFER_SIZE; } > DRAM .lcdbuffer2 (NOLOAD) : { _lcdbuf2 = .; . += LCD_BUFFER_SIZE; } > DRAM }