Could be a number of reasons : is the crystal oscillator working? I don't see your program setting port 2 up to enable it.
Here is an example "Blinky" program whose current consumption has been measured under 1 uA (with no LED!). A more complex version implementing a 1970's style LED digital watch runs on the 2553, again under 1 uA (display off!) in under a kilobyte.
It's not in C but I think it's pretty easy to read, and you may find settings you need in the Init_Clock or Start_Delay procedures.
with Interfaces; use Interfaces;
with CPU;
with timer_X;
procedure Blinky_xtal is
-- This example demonstrates a very small Ada application built
-- using gcc-msp intrinsic functions (for delay, manipulating interrupts).
-- New in Blinky_xtal: a 32768Hz crystal oscillator
use CPU.wdt;
use CPU.port1_r;
LED : Boolean renames p1out_bits(0);
begin
-- Initialise registers
wdtctl := wdtpw or wdthold;
p1dir := unsigned_8(CPU.cpu.bit0 or CPU.cpu.bit5);
p1sel := unsigned_8(CPU.cpu.bit5);
timer_X.Init_Clock;
timer_X.Start_Delay_MS(128);
loop
LED := True;
timer_X.Wait;
LED := False;
timer_X.Wait;
end loop;
end Blinky_xtal;
It uses a package "Timer_X" to handle the low level details of setting the oscillator and timer : the package spec is
with CPU;
package timer_X is
procedure Start_Delay_MS(MS : Natural);
procedure Init_Clock;
procedure Wait;
pragma Inline_Always(Wait);
private
procedure Handler;
pragma Machine_Attribute (Entity => Handler,
Attribute_Name => "interrupt",
Info => CPU.vectors.timera0_vector);
end timer_X;
and the package body (implementation) is
with CPU;
with System.GCC_Builtins;
with Interfaces; use Interfaces;
package body timer_X is
use CPU.ta2;
use CPU.bc2;
use CPU.port1_r;
procedure Handler is
begin
-- clear Low Power Mode in status reg copy on stack; loaded on RETI
System.GCC_Builtins.bic_status_register_on_exit(CPU.cpu.lpm3);
end;
procedure Init_Clock is
begin
-- MCLK is 1 MHz DCO
dcoctl := 0; -- slowest setting during setup
-- ClkCtrl 1 Calibration XT2off XTS DIVA
bcsctl1 := CPU.calibration.calbc1_1mhz or xt2off or diva_3;
dcoctl := CPU.calibration.caldco_1mhz;
-- set MClk to 1 MHz.
-- ClkCtrl 2 SELMx DIVMx SELS DIVSx DCOR
-- 0=DCO 0=div1 0=dco 3=div8 0=int
bcsctl2 := selm_0 or divm_0 ;
-- ClkCtrl 3 XT2Sx LFXT1Sx XCAPx XT2OF LFXT1OF
-- 1=6pf fault fault
bcsctl3 := xcap_2;
-- Connect oscillator pins from oscillator to crystal!
-- p2.7 select oscillator, dir=out, p2.6 select osc (dir=in)
p2dir := unsigned_8(CPU.cpu.bit7);
p2sel := unsigned_8(CPU.cpu.bit6 or CPU.cpu.bit7);
-- clear interrupt fault flag
CPU.cpu.ifg1_bits(1) := FALSE;
System.GCC_Builtins.bic_status_register(CPU.cpu.oscoff);
-- and enable interrupts!
System.GCC_Builtins.eint;
end;
procedure Start_Delay_MS(MS : Natural) is
begin
-- set Timer A to interrupt in MS ms
-- Control TASSEL IDx MCx TACLR TAIE TAIFG
-- 2=SMCLK 2=div4 1=ccr clear int+ no flag
ta0ctl := tassel_1 or id_2 or mc_1 or taclr; -- or taie;
-- Capture-Compare Register
ccr0 := Unsigned_16(MS-1);
-- Capture-Compare Control
-- CMx CCISx SCS SCCI CAP OUTMOD CCIE CCI OUT COV CCIFG
-- 0=nocap 0 0 0 0=comp 0 1=int
cctl0 := ccie;
end;
procedure Wait is
begin
-- enter LPM3.
System.GCC_Builtins.bis_status_register(CPU.cpu.lpm3);
end;
end timer_X;