Fortran texi: Fix typos

gcc/fortran/ChangeLog

	* gfc-internals.texi: Fix typos.
	* gfortran.texi: Likewise.
	* intrinsic.texi: Likewise.
	* invoke.texi: Likewise.

gcc/fortran/gfc-internals.texi

@@ -810,7 +810,7 @@ gfc_add_modify (block, var, build_int_cst (integer_type_node, 42));
 @end smallexample
 
 @node Converting Expressions
-@section Converting Expressons to tree
+@section Converting Expressions to tree
 
 Converting expressions to @code{tree} is done by functions called
 @code{gfc_conv_*}.

gcc/fortran/gfortran.texi

@@ -862,7 +862,7 @@ deferred character length left-hand sides are correctly handled but arrays
 are not yet fully implemented.
 
 @item Deferred-length character variables and scalar deferred-length character
-components of derived types are supported. (Note that array-valued compoents
+components of derived types are supported. (Note that array-valued components
 are not yet implemented.)
 
 @item Transferring of allocations via @code{MOVE_ALLOC}.
@@ -4168,7 +4168,7 @@ an array descriptor.  All other arrays pass the address of the
 first element of the array.  With @option{-fcoarray=lib}, the token
 and the offset belonging to nonallocatable coarrays dummy arguments
 are passed as hidden argument along the character length hidden
-arguments.  The token is an oparque pointer identifying the coarray
+arguments.  The token is an opaque pointer identifying the coarray
 and the offset is a passed-by-value integer of kind @code{C_PTRDIFF_T},
 denoting the byte offset between the base address of the coarray and
 the passed scalar or first element of the passed array.
@@ -4362,7 +4362,7 @@ typedef struct caf_reference_t {
 
 The references make up a single linked list of reference operations.  The
 @code{NEXT} member links to the next reference or NULL to indicate the end of
-the chain.  Component and array refs can be arbitrarly mixed as long as they
+the chain.  Component and array refs can be arbitrarily mixed as long as they
 comply to the Fortran standard.
 
 @emph{NOTES}
@@ -4683,7 +4683,7 @@ status. Note that for critical blocks, the locking is only required on one
 image; in the locking statement, the processor shall always pass an
 image index of one for critical-block lock variables
 (@code{CAF_REGTYPE_CRITICAL}). For lock types and critical-block variables,
-the initial value shall be unlocked (or, respecitively, not in critical
+the initial value shall be unlocked (or, respectively, not in critical
 section) such as the value false; for event types, the initial state should
 be no event, e.g. zero.
 @end table
@@ -5134,7 +5134,7 @@ error message why the operation is not permitted.
 @table @asis
 @item @emph{Description}:
 Acquire a lock on the given image on a scalar locking variable or for the
-given array element for an array-valued variable.  If the @var{aquired_lock}
+given array element for an array-valued variable.  If the @var{acquired_lock}
 is @code{NULL}, the function returns after having obtained the lock.  If it is
 non-@code{NULL}, then @var{acquired_lock} is assigned the value true (one) when
 the lock could be obtained and false (zero) otherwise.  Locking a lock variable
@@ -5142,7 +5142,7 @@ which has already been locked by the same image is an error.
 
 @item @emph{Syntax}:
 @code{void _gfortran_caf_lock (caf_token_t token, size_t index, int image_index,
-int *aquired_lock, int *stat, char *errmsg, size_t errmsg_len)}
+int *acquired_lock, int *stat, char *errmsg, size_t errmsg_len)}
 
 @item @emph{Arguments}:
 @multitable @columnfractions .15 .70
@@ -5151,7 +5151,7 @@ int *aquired_lock, int *stat, char *errmsg, size_t errmsg_len)}
 scalars, it is always 0.
 @item @var{image_index} @tab intent(in)  The ID of the remote image; must be a
 positive number.
-@item @var{aquired_lock} @tab intent(out) If not NULL, it returns whether lock
+@item @var{acquired_lock} @tab intent(out) If not NULL, it returns whether lock
 could be obtained.
 @item @var{stat} @tab intent(out) Stores the STAT=; may be NULL.
 @item @var{errmsg} @tab intent(out) When an error occurs, this will be set to

gcc/fortran/intrinsic.texi

@@ -8325,7 +8325,7 @@ Elemental function
 @item @emph{Arguments}:
 @multitable @columnfractions .15 .70
 @item @var{A}    @tab Shall be of type @code{INTEGER},
-@code{REAL}, or @code{COMPLEX} or or a boz-literal-constant.
+@code{REAL}, or @code{COMPLEX} or a boz-literal-constant.
 @item @var{KIND} @tab (Optional) An @code{INTEGER} initialization
 expression indicating the kind parameter of the result.
 @end multitable
@@ -10416,7 +10416,7 @@ Transformational function
 @item @var{DIM}   @tab (Optional) Shall be a scalar of type
 @code{INTEGER}, with a value between one and the rank of @var{ARRAY},
 inclusive.  It may not be an optional dummy argument.
-@item @var{MASK}  @tab (Opional) Shall be an array of type @code{LOGICAL},
+@item @var{MASK}  @tab (Optional) Shall be an array of type @code{LOGICAL},
 and conformable with @var{ARRAY}.
 @end multitable
 

gcc/fortran/invoke.texi

@@ -1826,7 +1826,7 @@ The default value for @var{n} is 30.
 
 @item -finline-matmul-limit=@var{n}
 @opindex @code{finline-matmul-limit}
-When front-end optimiztion is active, some calls to the @code{MATMUL}
+When front-end optimization is active, some calls to the @code{MATMUL}
 intrinsic function will be inlined.  This may result in code size
 increase if the size of the matrix cannot be determined at compile
 time, as code for both cases is generated.  Setting