FreeCalypso > hg > fc-magnetite
view src/cs/system/template/gsm_ds_motc139.template @ 180:24955aef4da3
t30.lib compiles
| author | Mychaela Falconia <falcon@freecalypso.org> |
|---|---|
| date | Thu, 13 Oct 2016 03:35:20 +0000 |
| parents | b54879bebfd3 |
| children |
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/* * Integrated Protocol Stack Linker command file (all components) * * Target : ARM * * Copyright (c) Texas Instruments 2002, Condat 2002 * * This version of the linker script template has been concocted * by Spacefalcon the Outlaw, based on gsm_ds_amd8_lj3.template, * in order to build the GSM firmware for the memory configuration * found in the Motorola C139. */ -c /* Autoinitialize variables at runtime */ /*********************************/ /* SPECIFY THE SYSTEM MEMORY MAP */ /*********************************/ MEMORY { /* CS0: Flash 4 Mbytes ****************************************************/ /* Interrupt Vectors Table */ I_MEM (RXI) : org = 0x00000000 len = 0x00000100 /* Boot Sector */ B_MEM (RXI) : org = 0x00000100 len = 0x00001f00 /* Magic Word for Calypso Boot ROM */ MWC_MEM (RXI) : org = 0x00002000 len = 0x00000004 fill = 0x0000001 /* Program Memory */ P_MEM1 (RXI) : org = 0x00010000 len = 0x00000700 P_MEM2 (RXI) : org = 0x00010700 len = 0x00000004 P_MEM3 (RXI) : org = 0x00010704 len = 0x003af8fc /* FFS Area */ FFS_MEM (RX) : org = 0x003C0000 len = 0x00030000 /**************************************************************************/ /* CS1: External SRAM 1 Mbytes ********************************************/ /* Data Memory */ /* *** HACK by Spacefalcon the Outlaw *** * * The starting Leonardo version (gsm_ds_amd8_lj3.template) had two * external SRAM regions: D_MEM1 and D_MEM2. When I tried removing * D_MEM2 and keeping only D_MEM1, the linker started behaving oddly * in that the sections were emitted in the wrong order, and the * addresses printed in the map file were bogus. The resulting m0 * images seemed to still work correctly, but I feel that having the * linker act "correctly" is better. * * My current hack-solution is to split the 1 MiB physical XRAM * into D_MEM1 and D_MEM2 of 512 KiB each. As it happens, the total * XRAM usage of the current firmware is a little below 512 KiB anyway. * * Update for C139: we only have 512 KiB in total now, but we can still * split the last 4 KiB off into D_MEM2. */ D_MEM1 (RW) : org = 0x01000000 len = 0x0007F000 D_MEM2 (RW) : org = 0x0107F000 len = 0x00001000 /**************************************************************************/ /* CS6: Calypso Internal SRAM 256 kbytes **********************************/ /* Code & Variables Memory */ S_MEM (RXW) : org = 0x00800000 len = 0x00040000 /**************************************************************************/ } /***********************************************/ /* SPECIFY THE SECTIONS ALLOCATION INTO MEMORY */ /***********************************************/ /* * Since the bootloader directly calls the INT_Initialize() routine located * in int.s, this int.s code must always be mapped at the same address * (usually in the second flash sector). Its length is about 0x500 bytes. * Then comes the code that need to be loaded into the internal RAM. */ SECTIONS { .intvecs : {} > I_MEM /* Interrupt Vectors Table */ .monitor : > B_MEM /* Monitor Constants & Code */ { $(CONST_BOOT_LIB) } .inttext : {} > P_MEM1 /* int.s Code */ .bss_dar : > D_MEM1 /* DAR SWE Variables */ { $(BSS_DAR_LIB) } /* * The .bss section should not be split to ensure it is initialized to 0 * each time the SW is reset. So the whole .bss is mapped either in D_MEM1 * or in D_MEM2. * * Falcon's note for K5A3281: see the comments above where the memory * regions are defined. */ .bss : > D_MEM1 | D_MEM2 /* Global & Static Variables */ { $(BSS_BOOT_LIB) } /* * All .bss sections, which must be mapped in internal RAM must be * grouped in order to initialized the corresponding memory to 0. * This initialization is done in int.s file before calling the Nucleus * routine. */ GROUP { S_D_Mem /* Label of start address of .bss section in Int. RAM */ .DintMem { /* * .bss sections of the application */ $(BSS_LIBS) } API_HISR_stack : {} E_D_Mem /* Label of end address of .bss section in Int. RAM */ } > S_MEM /* * .text and .const sections which must be mapped in internal RAM. */ .ldfl : {} > P_MEM2 /* Used to know the start load address */ GROUP load = P_MEM3, run = S_MEM { S_P_Mem /* Label of start address of .text & .const sections in Int. RAM */ .PIntMem { /* * .text and .const sections of the application. * * The .veneer sections correspond exactly to .text:v&n sections * implementing the veneer functions. The .text:v$n -> .veneer * translation is performed by PTOOL software when PTOOL_OPTIONS * environement variable is set to veneer_section. */ $(CONST_LIBS) } E_P_Mem /* Label of end address of .text and .const sections in Int. RAM */ } /* * The rest of the code is mapped in flash, however the trampolines * load address should be consistent with .text. */ COMMENT2START `trampolines load = P_MEM3, run = S_MEM COMMENT2END .text : {} > P_MEM3 /* Code */ /* * The rest of the constants is mapped in flash. * The .cinit section should not be split. */ .cinit : {} > P_MEM3 /* Initialization Tables */ .const : {} > P_MEM3 /* Constant Data */ KadaAPI : {} > P_MEM3 /* ROMized CLDC */ .javastack: {} >> D_MEM1 | D_MEM2 /* Java stack */ .stackandheap : > D_MEM1 /* System Stacks, etc... */ { /* Leave 20 32bit words for register pushes. */ . = align(8); . += 20 * 4; /* Stack for abort and/or undefined modes. */ exception_stack = .; /* Leave 38 32bit words for state saving on exceptions. */ _xdump_buffer = .; . += 38 * 4; . = align(8); /* Beginning of stacks and heap area - 2.75 kbytes (int.s) */ stack_segment = .; . += 0xB00; } .data : {} > D_MEM1 /* Initialized Data */ .sysmem : {} > D_MEM1 /* Dynamic Memory Allocation Area */ }