systemtap-common 2.9-2ubuntu2 / usr / share / systemtap / tapset / powerpc / registers.stp

/* Dwarfless register access for powerpc */

global _reg_offsets[44]

probe init {
	/* Same order as pt_regs */
	_reg_offsets["r0"] = 0
	_reg_offsets["r1"] = 8
	_reg_offsets["r2"] = 16
	_reg_offsets["r3"] = 24
	_reg_offsets["r4"] = 32
	_reg_offsets["r5"] = 40
	_reg_offsets["r6"] = 48
	_reg_offsets["r7"] = 56
	_reg_offsets["r8"] = 64
	_reg_offsets["r9"] = 72
	_reg_offsets["r10"] = 80
	_reg_offsets["r11"] = 88
	_reg_offsets["r12"] = 96
	_reg_offsets["r13"] = 104
	_reg_offsets["r14"] = 112
	_reg_offsets["r15"] = 120
	_reg_offsets["r16"] = 128
	_reg_offsets["r17"] = 136
	_reg_offsets["r18"] = 144
	_reg_offsets["r19"] = 152
	_reg_offsets["r20"] = 160
	_reg_offsets["r21"] = 168
	_reg_offsets["r22"] = 176
	_reg_offsets["r23"] = 184
	_reg_offsets["r24"] = 192
	_reg_offsets["r25"] = 200
	_reg_offsets["r26"] = 208
	_reg_offsets["r27"] = 216
	_reg_offsets["r28"] = 224
	_reg_offsets["r29"] = 232
	_reg_offsets["r30"] = 240
	_reg_offsets["r31"] = 248
	_reg_offsets["nip"] = 256
	_reg_offsets["msr"] = 264
	_reg_offsets["orig_gpr3"] = 272
	_reg_offsets["ctr"] = 280
	_reg_offsets["link"] = 288
	_reg_offsets["xer"] = 296
	_reg_offsets["ccr"] = 304
	_reg_offsets["softe"] = 312
	_reg_offsets["trap"] = 320
	_reg_offsets["dar"] = 328
	_reg_offsets["dsisr"] = 336
	_reg_offsets["result"] = 344

	/*
	 * If we ever need to support 32bit powerpc, we can
	 * get to the register offsets by using just a
	 * reg32_offset = _reg_offsets["reg"]/2
	 * or somesuch
	 */
}

function probing_32bit_app:long() %{ /* pure */
        STAP_RETVALUE = (CONTEXT->user_mode_p && _stp_is_compat_task());
%}

function arch_bytes:long() %{ /* pure */
  STAP_RETVALUE = sizeof(long);
%}

function uarch_bytes:long() {
  assert(user_mode(), "requires user mode")
  return probing_32bit_app() ? 4 : 8
}

function _stp_get_register_by_offset:long (offset:long) %{ /* pure */
	long value;
	struct pt_regs *regs;
	regs = (CONTEXT->user_mode_p ? CONTEXT->uregs : CONTEXT->kregs);
	if (!regs) {
		CONTEXT->last_error = "No registers available in this context";
		return;
	}
	if (STAP_ARG_offset < 0 || STAP_ARG_offset > sizeof(struct pt_regs) - sizeof(long)) {
		snprintf(CONTEXT->error_buffer, sizeof(CONTEXT->error_buffer),
				"Bad register offset: %lld",
				(long long)STAP_ARG_offset);
		CONTEXT->last_error = CONTEXT->error_buffer;
		return;
	}
	memcpy(&value, ((char *)regs) + STAP_ARG_offset, sizeof(value));
	STAP_RETVALUE = value;
%}

function _stp_sign_extend32:long (value:long) {
	if (value & 0x80000000)
		value |= (0xffffffff << 32)
	return value
}

function _stp_register:long (name:string, sign_extend:long) {
  assert(registers_valid(), "cannot access CPU registers in this context")
	offset = _reg_offsets[name]
  assert(offset != 0 || (name in _reg_offsets), "Unknown register: " . name)
	value = _stp_get_register_by_offset(offset)
	if (probing_32bit_app()) {
		if (sign_extend)
			value = _stp_sign_extend32(value)
		else
			value &= 0xffffffff
	}
	return value
}

/* Return the named register value as a signed value. */
function register:long (name:string) {
	return _stp_register(name, 1)
}

/*
 * Return the named register value as an unsigned value.  Specifically,
 * don't sign-extend the register value when promoting it to 64 bits.
 */
function u_register:long (name:string) {
	return _stp_register(name, 0)
}

/*
 * Return the value of function arg #argnum (1=first arg).
 * If truncate=1, mask off the top 32 bits.
 * If sign_extend=1 and (truncate=1 or the probepoint we've hit is in a
 * 32-bit app), sign-extend the 32-bit value.
 * If force64=1, return a 64-bit value even if we're in a 32-bit app.
 */
function _stp_arg:long (argnum:long, sign_extend:long, truncate:long)
{
	return _stp_arg2(argnum, sign_extend, truncate, 0)
}
function _stp_arg2:long (argnum:long, sign_extend:long, truncate:long,
			 force64:long)
{
	val = 0
  assert(!(argnum < 1 || argnum > 8), sprintf("Cannot access arg(%d)", argnum))

	if (argnum == 1)
		val = u_register("r3")
	else if (argnum == 2)
		val = u_register("r4")
	else if (argnum == 3)
		val = u_register("r5")
	else if (argnum == 4)
		val = u_register("r6")
	else if (argnum == 5)
		val = u_register("r7")
	else if (argnum == 6)
		val = u_register("r8")
	else if (argnum == 7)
		val = u_register("r9")
	else if (argnum == 8)
		val = u_register("r10")

	if ((truncate || @__compat_task) && !force64) {
		if (sign_extend)
			val = _stp_sign_extend32(val)
		else
			/* High bits may be garbage. */
			val = (val & 0xffffffff);
	}
	return val;
}

/* Return the value of function arg #argnum (1=first arg) as a signed int. */
function int_arg:long (argnum:long) {
	return _stp_arg2(argnum, 1, 1, 0)
}

/* Return the value of function arg #argnum (1=first arg) as an unsigned int. */
function uint_arg:long (argnum:long) {
	return _stp_arg2(argnum, 0, 1, 0)
}

function long_arg:long (argnum:long) {
	return _stp_arg2(argnum, 1, 0, 0)
}

function ulong_arg:long (argnum:long) {
	return _stp_arg2(argnum, 0, 0, 0)
}

function longlong_arg:long (argnum:long) {
	if (probing_32bit_app()) {
		highbits = _stp_arg2(argnum, 0, 1, 0)
		lowbits = _stp_arg2(argnum+1, 0, 1, 0)
		return ((highbits << 32) | lowbits)
	} else
		return _stp_arg2(argnum, 0, 0, 1)
}

function ulonglong_arg:long (argnum:long) {
	return longlong_arg(argnum)
}

function pointer_arg:long (argnum:long) {
	return _stp_arg2(argnum, 0, 0, 0)
}

function s32_arg:long (argnum:long) {
	return int_arg(argnum)
}

function u32_arg:long (argnum:long) {
	return uint_arg(argnum)
}

function s64_arg:long (argnum:long) {
	return longlong_arg(argnum)
}

function u64_arg:long (argnum:long) {
	return ulonglong_arg(argnum)
}

function asmlinkage() %{ /* pure */ %}

function fastcall() %{ /* pure */ %}

function regparm(n:long) %{
	snprintf(CONTEXT->error_buffer, sizeof(CONTEXT->error_buffer),
		"regparm is invalid on powerpc.");
	CONTEXT->last_error = CONTEXT->error_buffer;
%}