Operand 1 specifies the even register of an even-odd consecutive
pair of general purpose registers. For
instance, R4 would represent registers 4 and 5, while R8 would represent
registers 8 and 9. SRDL is used to shift the 64 bits in the even-odd pair as if they
comprised a single register. The shift
is to the right. The number of bits
that are shifted is indicated by Operand 2.
The second operand address is not
used to address data; instead, the base/displacement address is computed and
the rightmost 6 bits are treated as a binary integer which represents the
number of bits to be shifted. We will
call this value the shift factor.
This leads to two distinct ways of coding the shift factor:
1) Directly - The shift factor
is coded as a displacement. Consider
the example below.
SRDL R8,8
In the above shift, the
second operand, 8, is treated as a base/displacement address where 8 is the
displacement and the base register is omitted.
The effective address is 8. (See Explicit
Addressing.) When represented as an
address the rightmost 6 bits still represent the number 8, and so the bits in
registers 8 and 9 are shifted to the right by 8 bits.
2) Indirectly - The shift
factor is placed in a register and the register is mentioned as the base
register in the base/displacement address.
L R5,FACTOR PUT SHIFT FACTOR IN REG
SRDL R6,0(R5) NOW SHIFT INDIRECTLY
...
FACTOR DC F8 SHIFT FACTOR IS 8 BITS
In this case, the effective
address is computed by adding the contents of base register 5 (which is 8),
with the displacement of 0. The
effective address is again 8, and the rightmost 6 bits of this address indicate
that the shift factor is 8.
Each method has its uses.
The direct method is useful in situations where the number of bits you
want to shift is fixed. Coding directly
allows you to look at the instruction to determine the shift factor. On the other hand, the indirect method
allows the shift factor to be determined while the program is executing. If the shift factor cannot be determined
until the program is running, the indirect method must be used.
When shifting logically, bits shifted out on the right are lost,
while 0s replace bits on the left.
Consider the following instruction.
SRDL R8,6
This instruction represents
a right shift of registers 8 and 9 using a shift factor of 6. The shift factor has been coded
directly. As a result, 6 bits, 110000,
are shifted out of the register on the right.
Vacated bit positions on the left are replaced by 0s. This is illustrated in the diagram
below.
This instruction has an RS
format but the 4 low-order bits of the second byte are unused.
Some Unrelated SRDLs
R4 =
B11111111111111111111111111111111
R5 =
B11110000000000000000000000000000
SRDL R4,1 R4 =
B01111111111111111111111111111111
R5 =
B11111000000000000000000000000000
SRDL R4,2 R4 =
B00111111111111111111111111111111
R5 = B11111100000000000000000000000000
SRDL R4,3 R4 =
B00011111111111111111111111111111
R5 =
B11111110000000000000000000000000
SRDL R4,31 R4 =
B00000000000000000000000000000001
R5 =
B11111111111111111111111111111111
SRDL R4,32 R4 =
B00000000000000000000000000000000
R5 =
B11111111111111111111111111111111
L
R9,=F3
SRDL R4,0(R9) R4 = B00011111111111111111111111111111
R5 =
B11111110000000000000000000000000
L
R3,=F5
SRL
R4,0(R3) R4 = B00000111111111111111111111111111
R5 =
B11111111100000000000000000000000