smart-green-house/project_ZigBee/Projects/zstack/Tools/CC2530DB/f8w2530.xcl

/**************************************************************************************************
  Filename:       f8w2530.xcl
  Revised:        $Date: 2012-03-29 12:09:02 -0700 (Thu, 29 Mar 2012) $
  Revision:       $Revision: 29943 $

  Description:    This is a linker command line file for the IAR XLINK tool for the
                  CC2530 SoC and Z-Stack sample applications where the General Options
                  for location for constants and strings is "ROM mapped as data".


  Copyright 2009-2010 Texas Instruments Incorporated. All rights reserved.

  IMPORTANT: Your use of this Software is limited to those specific rights
  granted under the terms of a software license agreement between the user
  who downloaded the software, his/her employer (which must be your employer)
  and Texas Instruments Incorporated (the "License").  You may not use this
  Software unless you agree to abide by the terms of the License. The License
  limits your use, and you acknowledge, that the Software may not be modified,
  copied or distributed unless embedded on a Texas Instruments microcontroller
  or used solely and exclusively in conjunction with a Texas Instruments radio
  frequency transceiver, which is integrated into your product.  Other than for
  the foregoing purpose, you may not use, reproduce, copy, prepare derivative
  works of, modify, distribute, perform, display or sell this Software and/or
  its documentation for any purpose.

  YOU FURTHER ACKNOWLEDGE AND AGREE THAT THE SOFTWARE AND DOCUMENTATION ARE
  PROVIDED “AS IS" WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESS OR IMPLIED,
  INCLUDING WITHOUT LIMITATION, ANY WARRANTY OF MERCHANTABILITY, TITLE,
  NON-INFRINGEMENT AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL
  TEXAS INSTRUMENTS OR ITS LICENSORS BE LIABLE OR OBLIGATED UNDER CONTRACT,
  NEGLIGENCE, STRICT LIABILITY, CONTRIBUTION, BREACH OF WARRANTY, OR OTHER
  LEGAL EQUITABLE THEORY ANY DIRECT OR INDIRECT DAMAGES OR EXPENSES
  INCLUDING BUT NOT LIMITED TO ANY INCIDENTAL, SPECIAL, INDIRECT, PUNITIVE
  OR CONSEQUENTIAL DAMAGES, LOST PROFITS OR LOST DATA, COST OF PROCUREMENT
  OF SUBSTITUTE GOODS, TECHNOLOGY, SERVICES, OR ANY CLAIMS BY THIRD PARTIES
  (INCLUDING BUT NOT LIMITED TO ANY DEFENSE THEREOF), OR OTHER SIMILAR COSTS.

  Should you have any questions regarding your right to use this Software,
  contact Texas Instruments Incorporated at www.TI.com.

**************************************************************************************************/

////////////////////////////////////////////////////////////////////////////////
//
//
// Segment limits
// --------------
//
//
// XDATA available to the program.
//
// Reserving address 0x0 for NULL.
-D_XDATA_START=0x0001
-D_XDATA_END=0x1EFF
//
//
// The 8052 IDATA is overlayed on the SoC XDATA space from 0x1F00-0x1FFF.
//
-D_IDATA_END=0xFF              // Last address of Idata memory.
//
//
//    CODE
//
-D_CODE_START=0x0000
-D_CODE_END=0x7FFF             // Last address for ROOT bank.
//
-D_FIRST_BANK_ADDR=0x10000
//
//
//
// Special SFRs
// ------------
//
//    Register bank setup
//
-D?REGISTER_BANK=0             // Default register bank (0,1,2,3).
-D_REGISTER_BANK_START=0       // Start address for default register bank (00,08,10,18).
//
//
//    PDATA page setup
//
-D?PBANK_NUMBER=00             // High byte of 16-bit address to the PDATA area.
//
//
//    Virtual register setup
//    ----------------------
//
-D_BREG_START=0x00             // The bit address where the BREG segments starts.
                               // Must be placed on: _BREG_START%8=0 where _BREG_START <= 0x78.
-D?VB=0x20                     // ?VB is used when referencing BREG as whole byte.
                               // Must be placed on: ?VB=0x20+_BREG_START/8.
//
////////////////////////////////////////////////////////////////////////////////



////////////////////////////////////////////////////////////////////////////////
//
// IDATA memory
//

// Setup "bit" segments (only for '__no_init bool' variables).
-Z(BIT)BREG=_BREG_START
-Z(BIT)BIT_N=0-7F

-Z(DATA)REGISTERS+8=_REGISTER_BANK_START
-Z(DATA)BDATA_Z,BDATA_N,BDATA_I=20-2F
-Z(DATA)VREG+_NR_OF_VIRTUAL_REGISTERS=08-7F
-Z(DATA)PSP,XSP=08-7F
-Z(DATA)DOVERLAY=08-7F
-Z(DATA)DATA_I,DATA_Z,DATA_N=08-7F

-U(IDATA)0-7F=(DATA)0-7F
-Z(IDATA)IDATA_I,IDATA_Z,IDATA_N=08-_IDATA_END
-Z(IDATA)ISTACK+_IDATA_STACK_SIZE#08-_IDATA_END
-Z(IDATA)IOVERLAY=08-FF

////////////////////////////////////////////////////////////////////////////////
//
// ROM memory
//
//
// The following segments *must* be placed in the root bank. The order of
// placement also matters for these segments, which is why we use the -Z
// placement directive.
//
-Z(CODE)INTVEC=_CODE_START
-Z(CODE)BIT_ID,BDATA_ID,DATA_ID,IDATA_ID,IXDATA_ID,PDATA_ID,XDATA_ID=_CODE_START-_CODE_END
//
// Sleep PCON instruction must be 4-byte aligned.
//
-D_SLEEP_CODE_SPACE_START=(_CODE_END-7)
-D_SLEEP_CODE_SPACE_END=(_CODE_END)
-Z(CODE)SLEEP_CODE=_SLEEP_CODE_SPACE_START-_SLEEP_CODE_SPACE_END
//
// The following segments *must* be placed in the root bank, but the order
// of placement within the root bank is not important, which is why we use the
// -P directive here.
//
-P(CODE)CSTART,BANK_RELAYS,RCODE,DIFUNCT,NEAR_CODE=_CODE_START-_CODE_END
//
// Setup for constants located in code memory:
//
-P(CODE)CODE_C=_CODE_START-_CODE_END
//
// Define segments for const data in flash.
// First the segment with addresses as used by the program (flash mapped as XDATA)
-P(CONST)XDATA_ROM_C=0x8000-0xFFFF
//
// Then the segment with addresses as put in the hex file (flash bank 1)
-P(CODE)XDATA_ROM_C_FLASH=0x18000-0x1FFFF
//
// Finally link these segments (XDATA_ROM_C_FLASH is the initializer segment for XDATA_ROM_C,
// we map the flash in the XDATA address range instead of copying the data to RAM)
-QXDATA_ROM_C=XDATA_ROM_C_FLASH
//
// The directive below ensures that the remaining space in the root bank gets
// filled, then starts filling the banks.
//
-P(CODE)BANKED_CODE=_CODE_START-_CODE_END,0x18000-0x1FFFF,0x28000-0x2FFFF,0x38000-0x3FFFF,\
0x48000-0x4FFFF,0x58000-0x5FFFF,0x68000-0x6FFFF,0x78000-0x7F7FF

////////////////////////////////////////////////////////////////////////////////
//
// XDATA memory
//

-Z(XDATA)XSTACK+_XDATA_STACK_SIZE=_XDATA_START-_XDATA_END
-Z(XDATA)XDATA_Z,XDATA_I=_XDATA_START-_XDATA_END
-P(XDATA)XDATA_N=_XDATA_START-_XDATA_END

-cx51

////////////////////////////////////////////////////////////////////////////////
//
// Texas Instruments device specific
// =================================
//
//
// Layout of CODE banks
// -------------------
//
//-D_BANK0_START=0x08000
//-D_BANK0_END=0x0FFFF
//
//-D_BANK1_START=0x18000
//-D_BANK1_END=0x1FFFF
//
//-D_BANK2_START=0x28000
//-D_BANK2_END=0x2FFFF
//
//-D_BANK3_START=0x38000
//-D_BANK3_END=0x3FFFF
//
//-D_BANK4_START=0x48000
//-D_BANK4_END=0x4FFFF
//
//-D_BANK5_START=0x58000
//-D_BANK5_END=0x5FFFF
//
//-D_BANK6_START=0x68000
//-D_BANK6_END=0x6FFFF
//
//-D_BANK7_START=0x78000
//-D_BANK7_END=0x7FFFF
//
//
// Include these two lines when generating a .hex file for banked code model:
//-M(CODE)[(_CODEBANK_START+_FIRST_BANK_ADDR)-(_CODEBANK_END+_FIRST_BANK_ADDR)]*\
//_NR_OF_BANKS+_FIRST_BANK_ADDR=0x8000
//
//
// Internal flash used for NV address space: reserving 6 pages.
// NV memory segment size must coincide with page declarations in "hal_board_cfg.h" file.
//
-D_ZIGNV_ADDRESS_SPACE_START=(((_NR_OF_BANKS+1)*_FIRST_BANK_ADDR)-0x3800)
-D_ZIGNV_ADDRESS_SPACE_END=(_ZIGNV_ADDRESS_SPACE_START+0x2FFF)
-Z(CODE)ZIGNV_ADDRESS_SPACE=_ZIGNV_ADDRESS_SPACE_START-_ZIGNV_ADDRESS_SPACE_END
//
//
//
// The last available page of flash is reserved for special use as follows
// (addressing from the end of the page down):
//   16 bytes  Lock bits
//    8 bytes  IEEE address space (EUI-64)
//   22 bytes  Device Private Key (21 bytes + 1 byte pad to NV word size)
//   22 bytes  CA Public Key (22 bytes)
//   48 bytes  Implicit Certificate (48 bytes)
// 1932 bytes  Reserved for future Z-Stack use (1932 bytes)
//
-D_LOCK_BITS_ADDRESS_SPACE_START=(((_NR_OF_BANKS+1)*_FIRST_BANK_ADDR)-0x10)
-D_LOCK_BITS_ADDRESS_SPACE_END=(_LOCK_BITS_ADDRESS_SPACE_START+0x0F)
-Z(CODE)LOCK_BITS_ADDRESS_SPACE=_LOCK_BITS_ADDRESS_SPACE_START-_LOCK_BITS_ADDRESS_SPACE_END
//
-D_IEEE_ADDRESS_SPACE_START=(_LOCK_BITS_ADDRESS_SPACE_START-0x08)
-D_IEEE_ADDRESS_SPACE_END=(_IEEE_ADDRESS_SPACE_START+0x07)
-Z(CODE)IEEE_ADDRESS_SPACE=_IEEE_ADDRESS_SPACE_START-_IEEE_ADDRESS_SPACE_END
//
-D_DEV_PRIVATE_KEY_ADDRESS_SPACE_START=(_IEEE_ADDRESS_SPACE_START-0x16)
-D_DEV_PRIVATE_KEY_ADDRESS_SPACE_END=(_DEV_PRIVATE_KEY_ADDRESS_SPACE_START+0x15)
-Z(CODE)DEV_PRIVATE_KEY_ADDRESS_SPACE=_DEV_PRIVATE_KEY_ADDRESS_SPACE_START-_DEV_PRIVATE_KEY_ADDRESS_SPACE_END
//
-D_CA_PUBLIC_KEY_ADDRESS_SPACE_START=(_DEV_PRIVATE_KEY_ADDRESS_SPACE_START-0x16)
-D_CA_PUBLIC_KEY_ADDRESS_SPACE_END=(_CA_PUBLIC_KEY_ADDRESS_SPACE_START+0x15)
-Z(CODE)CA_PUBLIC_KEY_ADDRESS_SPACE=_CA_PUBLIC_KEY_ADDRESS_SPACE_START-_CA_PUBLIC_KEY_ADDRESS_SPACE_END
//
-D_IMPLICIT_CERTIFICATE_ADDRESS_SPACE_START=(_CA_PUBLIC_KEY_ADDRESS_SPACE_START-0x30)
-D_IMPLICIT_CERTIFICATE_ADDRESS_SPACE_END=(_IMPLICIT_CERTIFICATE_ADDRESS_SPACE_START+0x2F)
-Z(CODE)IMPLICIT_CERTIFICATE_ADDRESS_SPACE=_IMPLICIT_CERTIFICATE_ADDRESS_SPACE_START-_IMPLICIT_CERTIFICATE_ADDRESS_SPACE_END
//
-D_RESERVED_ADDRESS_SPACE_START=(_IMPLICIT_CERTIFICATE_ADDRESS_SPACE_START-0x78C)
-D_RESERVED_ADDRESS_SPACE_END=(_RESERVED_ADDRESS_SPACE_START+0x78B)
-Z(CODE)RESERVED_ADDRESS_SPACE=_RESERVED_ADDRESS_SPACE_START-_RESERVED_ADDRESS_SPACE_END
//
////////////////////////////////////////////////////////////////////////////////