Intel® Fortran Compiler Classic and Intel® Fortran Compiler Developer Guide and Reference

ID 767251
Date 11/07/2023
Public

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Document Table of Contents

init, Qinit

Lets you initialize a class of variables to zero or to various numeric exceptional values.

Syntax

Linux:

-init=keyword [, keyword ]

Windows:

/Qinit:keyword [, keyword ]

Arguments

keyword

Specifies the initial value for a class of variables. Possible values are:

[no]arrays

Determines whether the compiler initializes variables that are arrays or scalars. Specifying arrays initializes variables that are arrays or scalars. Specifying noarrays or neither arrays or noarrays initializes only variables that are scalars. You must also specify at least one other keyword when you specify keyword noarrays.

huge or minus_huge

Determines both of the following:

  • whether the compiler initializes to the largest representable positive or negative real value all uninitialized variables of intrinsic type REAL or COMPLEX that are saved, local, automatic, or allocated variables

  • whether the compiler initializes to the largest representable positive or negative integer value all uninitialized variables of intrinsic type INTEGER that are saved, local, automatic, or allocated variables

infinity or minus_infinity

Determines whether the compiler initializes to positive or negative Infinity all uninitialized variables of intrinsic type REAL or COMPLEX that are saved, local, automatic, or allocated variables.

[no]snan

Determines whether the compiler initializes to signaling NaN all uninitialized variables of intrinsic type REAL or COMPLEX that are saved, local, automatic, or allocated variables.

tiny or minus_tiny

Determines whether the compiler initializes to the smallest representable positive or negative real value all uninitialized variables of intrinsic type REAL or COMPLEX that are saved, local, automatic, or allocated variables.

[no]zero

Determines whether the compiler initializes to zero all uninitialized variables of intrinsic type REAL, COMPLEX, INTEGER, or LOGICAL that are saved, local, automatic, or allocated variables.

Option /Qinit:[no]zero replaces option /Qzero[-] (Windows*) , and option -init=[no]zero replaces option -[no]zero (Linux*).

Default

OFF

No initializations are performed by default if you do not specify any of these options.

Description

This option lets you initialize a class of variables to zero or to one or more of the various numeric exceptional values positive or negative huge, positive or negative Infinity, signaling NaN, or positive or negative tiny.

If you only specify the keyword [minus_]huge, [minus_]infinity, snan, [minus_]tiny, or zero, option [Q]init affects only scalar variables. To apply an initialization to arrays as well, you must also specify the keyword arrays.

If you have specified an ALLOCATE statement and you specify one or more [Q]init keywords, the initializers are applied to the memory that has been allocated by the ALLOCATE statement.

Keywords are applied to the various numeric types in the following order:

  • For REAL and COMPLEX variables, keywords [minus_]huge, [minus_]infinity, snan, [minus_]tiny, and zero initialize to the specified value.

  • For INTEGER variables, keywords [minus_]huge and zero initialize to the specified value.

  • For LOGICAL variables, keyword zero initializes to .FALSE..

The following classes of variables are initialized by the [Q]init option:

  • Variables of intrinsic numeric type, that is, of type COMPLEX, INTEGER, LOGICAL, or REAL, of any KIND

  • SAVEd scalar or array variables, not in the main program, that are not initialized in the source code

  • Local scalars and arrays

  • Module variables that are not initialized in the source code

  • Automatic arrays

  • Integers can be set to zero, huge, or minus_huge.

  • In a COMPLEX variable, each of the real and imaginary parts is separately initialized as a REAL.

The following are general restrictions for this option:

  • The keywords [minus_]infinity, snan, and [minus_]tiny only affect certain variables of REAL or COMPLEX type.

  • You cannot initialize variables in equivalence groups to any of the numeric exceptional values.

  • In an equivalence group, if no member of that equivalence group has an explicit initialization or a default initialization (in the case of a derived type), a variable in that equivalence group can be initialized to zero but not to any of the numeric exceptional values.

  • Derived types, arrays of derived types, and their components will not be initialized.

  • Dummy arguments including adjustable arrays will not be initialized.

  • Variables in COMMON will not be initialized.

The following spellings all cause the same behavior, that is, they initialize certain numeric arrays and scalars to zero:

  • [Q]init zero [Q]init arrays

  • [Q]init arrays [Q]init zero

  • [Q]init zero, arrays

  • [Q]init arrays, zero

Combinations of keywords will override each other in a left-to-right fashion as follows:

  • zero and nozero override each other.

  • snan and nosnan override each other.

  • huge and minus_huge override each other.

  • tiny and minus_tiny override each other.

  • infinity, minus_infinity, and snan will all override each other.

Because a REAL or COMPLEX variable can be initialized to huge or minus_huge, infinity or minus_infinity, tiny or minus_tiny, snan, or zero, these initializations are applied in the following order:

  1. snan

  2. infinity or minus_infinity

  3. tiny or minus_tiny

  4. huge or minus_huge

  5. zero

Because an INTEGER variable can be initialized to huge or minus_huge, or zero, these initializations are applied in the following order:

  1. huge or minus_huge

  2. zero

For example, if the you specify [Q]init zero, minus_huge, snan when compiling the following program:

program test 
real X 
integer K 
complex C 
end 

The variable X will be initialized with a signaling NaN (snan), variable K will be initialized to the integer value minus_huge, and the real and imaginary parts of variable C will be initialized to a signaling NaN (snan) in each.

If you specify [Q]init snan, the floating-point exception handling flags will be set to trap signaling NaN and halt so that when such a value is trapped at runtime, the Fortran library can catch the usage, display an error message about a possible uninitialized variable, display a traceback, and stop execution. You can use the debugger to determine where in your code this uninitialized variable is being referenced when execution stops.

Setting the option [Q]init snan implicitly sets the option fpe 0. A compile time warning will occur if you specify both option fpe 3 and option [Q]init snan on the command line. In this case, fpe 3 is ignored.

NOTE:

If you build with optimization, the compiler may speculate floating-point operations, assuming the default floating-point environment in which floating-point exceptions are masked. When you add [Q]init snan, this speculation may result in exceptions, unrelated to uninitialized variables, that now get trapped. To avoid this, reduce the optimization level to /O1 or /Od (Windows*), or -O1 or -O0 (Linux*) when doing uninitialized variable detection.

If you wish to maintain optimization, you should add option [Q]fp-speculation safe to disable speculation when there is a possibility that the speculation may result in a floating-point exception.

NOTE:

To avoid possible performance issues, you should only use [Q]init for debugging (for example, [Q]init zero) and checking for uninitialized variables (for example, [Q]init snan).

Use option [Q]save if you wish all variables to be specifically marked as SAVE.

IDE Equivalent

Visual Studio: Data > Initialize Variables to Signaling NaN

Data > Initialize Variables to Zero

Data > Initialize Arrays as well as Scalars

Alternate Options

None

Example

The following example shows how to initialize scalars of intrinsic type REAL and COMPLEX to signaling NaN, and scalars of intrinsic type INTEGER and LOGICAL to zero:

-init=snan,zero               ! Linux systems
/Qinit:snan,zero              ! Windows systems

The following example shows how to initialize scalars and arrays of intrinsic type REAL and COMPLEX to signaling NaN, and scalars and arrays of intrinsic type INTEGER and LOGICAL to zero:

-init=zero -init=snan –init=arrays       ! Linux systems
/Qinit:zero /Qinit:snan /Qinit:arrays    ! Windows systems

To see an example of how to use option [Q]init for detection of uninitialized floating-point variables at runtime, see the article titled Detection of Uninitialized Floating-point Variables in Intel® Fortran.

See Also