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A B C D F G I J L M N P R S T W

l2d

Operation

Convert long to double

Format

l2d

Forms

l2d = 138 (0x8a)

Operand Stack

..., value ..., result

Description

The value on the top of the operand stack must be of type long. It is popped from the operand stack and converted to a double result using IEEE 754 round to nearest mode. The result is pushed onto the operand stack.

Notes

The l2d instruction performs a widening primitive conversion (§2.6.2) that may lose precision because values of type double have only 53 significand bits.


l2f

Operation

Convert long to float

Format

l2f

Forms

l2f = 137 (0x89)

Operand Stack

..., value ..., result

Description

The value on the top of the operand stack must be of type long. It is popped from the operand stack and converted to a float result using IEEE 754 round to nearest mode. The result is pushed onto the operand stack.

Notes

The l2f instruction performs a widening primitive conversion (§2.6.2) that may lose precision because values of type float have only 24 significand bits.


l2i

Operation

Convert long to int

Format

l2i

Forms

l2i = 136 (0x88)

Operand Stack

..., value ..., result

Description

The value on the top of the operand stack must be of type long. It is popped from the operand stack and converted to an int result by taking the low-order 32 bits of the long value and discarding the high-order 32 bits. The result is pushed onto the operand stack.

Notes

The l2i instruction performs a narrowing primitive conversion (§2.6.3). It may lose information about the overall magnitude of value. The result may also not have the same sign as value.


ladd

Operation

Add long

Format

ladd

Forms

ladd = 97 (0x61)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. The values are popped from the operand stack. The long result is value1 + value2. The result is pushed onto the operand stack.

The result is the 64 low-order bits of the true mathematical result in a sufficiently wide two's-complement format, represented as a value of type long. If overflow occurs, the sign of the result may not be the same as the sign of the mathematical sum of the two values.

Despite the fact that overflow may occur, execution of an ladd instruction never throws a runtime exception.


laload

Operation

Load long from array

Format

laload

Forms

laload = 47 (0x2f)

Operand Stack

..., arrayref, index ..., value

Description

The arrayref must be of type reference and must refer to an array whose components are of type long. The index must be of type int. Both arrayref and index are popped from the operand stack. The long value in the component of the array at index is retrieved and pushed onto the operand stack.

Runtime Exceptions

If arrayref is null, laload throws a NullPointerException.

Otherwise, if index is not within the bounds of the array referenced by arrayref, the laload instruction throws an ArrayIndexOutOfBoundsException.


land

Operation

Boolean AND long

Format

land

Forms

land = 127 (0x7f)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. They are popped from the operand stack. A long result is calculated by taking the bitwise AND of value1 and value2. The result is pushed onto the operand stack.


lastore

Operation

Store into long array

Format

lastore

Forms

lastore = 80 (0x50)

Operand Stack

..., arrayref, index, value ...

Description

The arrayref must be of type reference and must refer to an array whose components are of type long. The index must be of type int, and value must be of type long. The arrayref, index, and value are popped from the operand stack. The long value is stored as the component of the array indexed by index.

Runtime Exceptions

If arrayref is null, lastore throws a NullPointerException.

Otherwise, if index is not within the bounds of the array referenced by arrayref, the lastore instruction throws an ArrayIndexOutOfBoundsException.


lcmp

Operation

Compare long

Format

lcmp

Forms

lcmp = 148 (0x94)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. They are both popped from the operand stack, and a signed integer comparison is performed. If value1 is greater than value2, the int value 1 is pushed onto the operand stack. If value1 is equal to value2, the int value 0 is pushed onto the operand stack. If value1 is less than value2, the int value -1 is pushed onto the operand stack.


lconst_<l>

Operation

Push long constant

Format

lconst_<l>

Forms

lconst_0 = 9 (0x9) lconst_1 = 10 (0xa)

Operand Stack

... ..., <l>

Description

Push the long constant <l> (0 or 1) onto the operand stack.


ldc

Operation

Push item from runtime constant pool

Format

ldc
index

Forms

ldc = 18 (0x12)

Operand Stack

... ..., value

Description

The index is an unsigned byte that must be a valid index into the runtime constant pool of the current class (§3.6). The runtime constant pool entry at index either must be a runtime constant of type int or float, or must be a symbolic reference to a string literal (§5.1).

If the runtime constant pool entry is a runtime constant of type int or float, the numeric value of that runtime constant is pushed onto the operand stack as an int or float, respectively.

Otherwise, the runtime constant pool entry must be a reference to an instance of class String representing a string literal (§5.1). A reference to that instance, value, is pushed onto the operand stack.

Notes

The ldc instruction can only be used to push a value of type float taken from the float value set (§3.3.2) because a constant of type float in the constant pool (§4.4.4) must be taken from the float value set.


ldc_w

Operation

Push item from runtime constant pool (wide index)

Format

ldc_w
indexbyte1
indexbyte2

Forms

ldc_w = 19 (0x13)

Operand Stack

... ..., value

Description

The unsigned indexbyte1 and indexbyte2 are assembled into an unsigned 16-bit index into the runtime constant pool of the current class (§3.6), where the value of the index is calculated as (indexbyte1 << 8) | indexbyte2. The index must be a valid index into the runtime constant pool of the current class. The runtime constant pool entry at the index either must be a runtime constant of type int or float, or must be a symbolic reference to a string literal (§5.1).

If the runtime constant pool entry is a runtime constant of type int or float, the numeric value of that runtime constant is pushed onto the operand stack as an int or float, respectively.

Otherwise, the runtime constant pool entry must be a reference to an instance of class String representing a string literal (§5.1). A reference to that instance, value, is pushed onto the operand stack.

Notes

The ldc_w instruction is identical to the ldc instruction except for its wider runtime constant pool index.

The ldc_w instruction can only be used to push a value of type float taken from the float value set (§3.3.2) because a constant of type float in the constant pool (§4.4.4) must be taken from the float value set.


ldc2_w

Operation

Push long or double from runtime constant pool (wide index)

Format

ldc2_w
indexbyte1
indexbyte2

Forms

ldc2_w = 20 (0x14)

Operand Stack

... ..., value

Description

The unsigned indexbyte1 and indexbyte2 are assembled into an unsigned 16-bit index into the runtime constant pool of the current class (§3.6), where the value of the index is calculated as (indexbyte1 << 8) | indexbyte2. The index must be a valid index into the runtime constant pool of the current class. The runtime constant pool entry at the index must be a runtime constant of type long or double (§5.1). The numeric value of that runtime constant is pushed onto the operand stack as a long or double, respectively.

Notes

Only a wide-index version of the ldc2_w instruction exists; there is no ldc2 instruction that pushes a long or double with a single-byte index.

The ldc2_w instruction can only be used to push a value of type double taken from the double value set (§3.3.2) because a constant of type double in the constant pool (§4.4.5) must be taken from the double value set.


ldiv

Operation

Divide long

Format

ldiv

Forms

ldiv = 109 (0x6d)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. The values are popped from the operand stack. The long result is the value of the Java programming language expression value1 / value2. The result is pushed onto the operand stack.

A long division rounds towards 0; that is, the quotient produced for long values in n / d is a long value q whose magnitude is as large as possible while satisfying . Moreover, q is positive when and n and d have the same sign, but q is negative when and n and d have opposite signs.

There is one special case that does not satisfy this rule: if the dividend is the negative integer of largest possible magnitude for the long type and the divisor is -1, then overflow occurs and the result is equal to the dividend; despite the overflow, no exception is thrown in this case.

Runtime Exception

If the value of the divisor in a long division is 0, ldiv throws an ArithmeticException.


lload

Operation

Load long from local variable

Format

lload
index

Forms

lload = 22 (0x16)

Operand Stack

... ..., value

Description

The index is an unsigned byte. Both index and index + 1 must be indices into the local variable array of the current frame (§3.6). The local variable at index must contain a long. The value of the local variable at index is pushed onto the operand stack.

Notes

The lload opcode can be used in conjunction with the wide instruction to access a local variable using a two-byte unsigned index.


lload_<n>

Operation

Load long from local variable

Format

lload_<n>

Forms

lload_0 = 30 (0x1e) lload_1 = 31 (0x1f) lload_2 = 32 (0x20) lload_3 = 33 (0x21)

Operand Stack

... ..., value

Description

Both <n> and <n> + 1 must be indices into the local variable array of the current frame (§3.6). The local variable at <n> must contain a long. The value of the local variable at <n> is pushed onto the operand stack.

Notes

Each of the lload_<n> instructions is the same as lload with an index of <n>, except that the operand <n> is implicit.


lmul

Operation

Multiply long

Format

lmul

Forms

lmul = 105 (0x69)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. The values are popped from the operand stack. The long result is value1 * value2. The result is pushed onto the operand stack.

The result is the 64 low-order bits of the true mathematical result in a sufficiently wide two's-complement format, represented as a value of type long. If overflow occurs, the sign of the result may not be the same as the sign of the mathematical sum of the two values.

Despite the fact that overflow may occur, execution of an lmul instruction never throws a runtime exception.


lneg

Operation

Negate long

Format

lneg

Forms

lneg = 117 (0x75)

Operand Stack

..., value ..., result

Description

The value must be of type long. It is popped from the operand stack. The long result is the arithmetic negation of value, -value. The result is pushed onto the operand stack.

For long values, negation is the same as subtraction from zero. Because the Java virtual machine uses two's-complement representation for integers and the range of two's-complement values is not symmetric, the negation of the maximum negative long results in that same maximum negative number. Despite the fact that overflow has occurred, no exception is thrown.

For all long values x, -x equals (~x) + 1.


lookupswitch

Operation

Access jump table by key match and jump

Format

lookupswitch
<0-3 byte pad\>
defaultbyte1
defaultbyte2
defaultbyte3
defaultbyte4
npairs1
npairs2
npairs3
npairs4
match-offset pairs...

Forms

lookupswitch = 171 (0xab)

Operand Stack

..., key ...

Description

A lookupswitch is a variable-length instruction. Immediately after the lookupswitch opcode, between zero and three null bytes (zeroed bytes, not the null object) are inserted as padding. The number of null bytes is chosen so that the defaultbyte1 begins at an address that is a multiple of four bytes from the start of the current method (the opcode of its first instruction). Immediately after the padding follow a series of signed 32-bit values: default, npairs, and then npairs pairs of signed 32-bit values. The npairs must be greater than or equal to 0. Each of the npairs pairs consists of an int match and a signed 32-bit offset. Each of these signed 32-bit values is constructed from four unsigned bytes as (byte1 << 24) | (byte2 << 16) | (byte3 << 8) | byte4.

The table match-offset pairs of the lookupswitch instruction must be sorted in increasing numerical order by match.

The key must be of type int and is popped from the operand stack. The key is compared against the match values. If it is equal to one of them, then a target address is calculated by adding the corresponding offset to the address of the opcode of this lookupswitch instruction. If the key does not match any of the match values, the target address is calculated by adding default to the address of the opcode of this lookupswitch instruction. Execution then continues at the target address.

The target address that can be calculated from the offset of each match-offset pair, as well as the one calculated from default, must be the address of an opcode of an instruction within the method that contains this lookupswitch instruction.

Notes

The alignment required of the 4-byte operands of the lookupswitch instruction guarantees 4-byte alignment of those operands if and only if the method that contains the lookupswitch is positioned on a 4-byte boundary.

The match-offset pairs are sorted to support lookup routines that are quicker than linear search.


lor

Operation

Boolean OR long

Format

lor

Forms

lor = 129 (0x81)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. They are popped from the operand stack. A long result is calculated by taking the bitwise inclusive OR of value1 and value2. The result is pushed onto the operand stack.


lrem

Operation

Remainder long

Format

lrem

Forms

lrem = 113 (0x71)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. The values are popped from the operand stack. The long result is value1 - (value1 / value2) * value2. The result is pushed onto the operand stack.

The result of the lrem instruction is such that (a/b)*b + (a%b) is equal to a. This identity holds even in the special case in which the dividend is the negative long of largest possible magnitude for its type and the divisor is -1 (the remainder is 0). It follows from this rule that the result of the remainder operation can be negative only if the dividend is negative and can be positive only if the dividend is positive; moreover, the magnitude of the result is always less than the magnitude of the divisor.

Runtime Exception

If the value of the divisor for a long remainder operator is 0, lrem throws an ArithmeticException.


lreturn

Operation

Return long from method

Format

lreturn

Forms

lreturn = 173 (0xad)

Operand Stack

..., value [empty]

Description

The current method must have return type long. The value must be of type long. If the current method is a synchronized method, the monitor acquired or reentered on invocation of the method is released or exited (respectively) as if by execution of a monitorexit instruction. If no exception is thrown, value is popped from the operand stack of the current frame (§3.6) and pushed onto the operand stack of the frame of the invoker. Any other values on the operand stack of the current method are discarded.

The interpreter then returns control to the invoker of the method, reinstating the frame of the invoker.

Runtime Exceptions

If the current method is a synchronized method and the current thread is not the owner of the monitor acquired or reentered on invocation of the method, lreturn throws an IllegalMonitorStateException. This can happen, for example, if a synchronized method contains a monitorexit instruction, but no monitorenter instruction, on the object on which the method is synchronized.

Otherwise, if the virtual machine implementation enforces the rules on structured use of locks described in Section 8.13 and if the first of those rules is violated during invocation of the current method, then lreturn throws an IllegalMonitorStateException.


lshl

Operation

Shift left

Format

lshl

long

Forms

lshl = 121 (0x79)

Operand Stack

..., value1, value2 ..., result

Description

The value1 must be of type long, and value2 must be of type int. The values are popped from the operand stack. A long result is calculated by shifting value1 left by s bit positions, where s is the low 6 bits of value2. The result is pushed onto the operand stack.

Notes

This is equivalent (even if overflow occurs) to multiplication by 2 to the power s. The shift distance actually used is therefore always in the range 0 to 63, inclusive, as if value2 were subjected to a bitwise logical AND with the mask value 0x3f.


lshr

Operation

Arithmetic shift right long

Format

lshr

Forms

lshr = 123 (0x7b)

Operand Stack

..., value1, value2 ..., result

Description

The value1 must be of type long, and value2 must be of type int. The values are popped from the operand stack. A long result is calculated by shifting value1 right by s bit positions, with sign extension, where s is the value of the low 6 bits of value2. The result is pushed onto the operand stack.

Notes

The resulting value is , where s is value2 & 0x3f. For nonnegative value1, this is equivalent to truncating long division by 2 to the power s. The shift distance actually used is therefore always in the range 0 to 63, inclusive, as if value2 were subjected to a bitwise logical AND with the mask value 0x3f.


lstore

Operation

Store long into local variable

Format

lstore
index

Forms

lstore = 55 (0x37)

Operand Stack

..., value ...

Description

The index is an unsigned byte. Both index and index + 1 must be indices into the local variable array of the current frame (§3.6). The value on the top of the operand stack must be of type long. It is popped from the operand stack, and the local variables at index and index + 1 are set to value.

Notes

The lstore opcode can be used in conjunction with the wide instruction to access a local variable using a two-byte unsigned index.


lstore_<n>

Operation

Store long into local variable

Format

lstore_<n>

Forms

lstore_0 = 63 (0x3f) lstore_1 = 64 (0x40) lstore_2 = 65 (0x41) lstore_3 = 66 (0x42)

Operand Stack

..., value ...

Description

Both <n> and <n> + 1 must be indices into the local variable array of the current frame (§3.6). The value on the top of the operand stack must be of type long. It is popped from the operand stack, and the local variables at <n> and <n> + 1 are set to value.

Notes

Each of the lstore_<n> instructions is the same as lstore with an index of <n>, except that the operand <n> is implicit.


lsub

Operation

Subtract long

Format

lsub

Forms

lsub = 101 (0x65)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. The values are popped from the operand stack. The long result is value1 - value2. The result is pushed onto the operand stack.

For long subtraction, a-b produces the same result as a+(-b). For long values, subtraction from zero is the same as negation.

The result is the 64 low-order bits of the true mathematical result in a sufficiently wide two's-complement format, represented as a value of type long. If overflow occurs, then the sign of the result may not be the same as the sign of the mathematical sum of the two values.

Despite the fact that overflow may occur, execution of an lsub instruction never throws a runtime exception.


lushr

Operation

Logical shift right long

Format

lushr

Forms

lushr = 125 (0x7d)

Operand Stack

..., value1, value2 ..., result

Description

The value1 must be of type long, and value2 must be of type int. The values are popped from the operand stack. A long result is calculated by shifting value1 right logically (with zero extension) by the amount indicated by the low 6 bits of value2. The result is pushed onto the operand stack.

Notes

If value1 is positive and s is value2 & 0x3f, the result is the same as that of value1 >> s; if value1 is negative, the result is equal to the value of the expression (value1 >> s) + (2L << ~s). The addition of the (2L << ~s) term cancels out the propagated sign bit. The shift distance actually used is always in the range 0 to 63, inclusive.


lxor

Operation

Boolean XOR long

Format

lxor

Forms

lxor = 131 (0x83)

Operand Stack

..., value1, value2 ..., result

Description

Both value1 and value2 must be of type long. They are popped from the operand stack. A long result is calculated by taking the bitwise exclusive OR of value1 and value2. The result is pushed onto the operand stack.


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The JavaTM Virtual Machine Specification
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