--- /dev/null
+# Created by Octave 3.6.1, Tue Apr 03 18:18:25 2012 UTC <root@t61>
+# name: cache
+# type: cell
+# rows: 3
+# columns: 6
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 6
+concat
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 733
+ -- Function File: X = concat (A, B)
+ -- Function File: X = concat (A, B, DIM)
+ Concatenate two matrices regardless of their type. Due to the
+ implementation of the matrix concatenation in Octave being
+ hard-coded for the types it knowns, user types can not use the
+ matrix concatenation operator. Thus for the _Galois_ and _Fixed
+ Point_ types, the in-built matrix concatenation functions will
+ return a matrix value as their solution.
+
+ This function allows these types to be concatenated. If called
+ with a user type that is not known by this function, the in-built
+ concatenate function is used.
+
+ If DIM is 1, then the matrices are concatenated, else if DIM is 2,
+ they are stacked.
+
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 50
+Concatenate two matrices regardless of their type.
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 19
+create_lookup_table
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 193
+ -- Function File: TABLE = create_lookup_table (X, Y)
+ Creates a lookup table betwen the vectors X and Y. If X is not in
+ increasing order, the vectors are sorted before being stored.
+
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 50
+Creates a lookup table betwen the vectors X and Y.
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 10
+fixedpoint
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 1356
+ -- Function File: fixedpoint ('help')
+ -- Function File: fixedpoint ('info')
+ -- Function File: fixedpoint ('info', MOD)
+ -- Function File: fixedpoint ('test')
+ -- Function File: fixedpoint ('test', MOD)
+ Manual and test code for the Octave Fixed Point toolbox. There are
+ 5 possible ways to call this function.
+
+ `fixedpoint ('help')'
+ Display this help message. Called with no arguments, this
+ function also displays this help message
+
+ `fixedpoint ('info')'
+ Open the Fixed Point toolbox manual
+
+ `fixedpoint ('info', MOD)'
+ Open the Fixed Point toolbox manual at the section specified
+ by MOD
+
+ `fixedpoint ('test')'
+ Run all of the test code for the Fixed Point toolbox. MOD.
+
+ Valid values for the varibale MOD are
+
+ 'basics'
+ The section describing the use of the fixed point toolbox
+ within Octave
+
+ 'programming'
+ The section descrining how to use the fixed-point type with
+ oct-files
+
+ 'example'
+ The section describing an in-depth example of the use of the
+ fixed-point type
+
+ 'reference'
+ The refernce section of all of the specific fixed point
+ operators and functions
+
+ Please note that this function file should be used as an example
+ of the use of this toolbox.
+
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 56
+Manual and test code for the Octave Fixed Point toolbox.
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 5
+float
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 203
+ -- Function File: Y = float (X)
+ Converts a fixed point object to the equivalent floating point
+ object. This is equivalent to `X.x' if `isfixed(X)' returns true,
+ and returns X otherwise.
+
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 70
+Converts a fixed point object to the equivalent floating point object.
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 5
+fsort
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 712
+ -- Function File: [S, I] = fsort (X)
+ Return a copy of the fixed point variable X with the elements
+ arranged in increasing order. For matrices, `fsort' orders the
+ elements in each column.
+
+ For example,
+
+ fsort (fixed(4,0,[1, 2; 2, 3; 3, 1]))
+ => 1 1
+ 2 2
+ 3 3
+
+ The `fsort' function may also be used to produce a matrix
+ containing the original row indices of the elements in the sorted
+ matrix. For example,
+
+ [s, i] = sort ([1, 2; 2, 3; 3, 1])
+ => s = 1 1
+ 2 2
+ 3 3
+ => i = 1 3
+ 2 1
+ 3 2
+
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 80
+Return a copy of the fixed point variable X with the elements arranged
+in increa
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 12
+lookup_table
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 621
+ -- Function File: Y = lookup_table (TABLE, X)
+ -- Function File: Y = lookup_table (TABLE, X, INTERP, EXTRAP)
+ Using the lookup table created by "create_lookup_table", find the
+ value Y corresponding to X. With two arguments the lookup is done
+ to the nearest value below in the table less than the desired
+ value. With three arguments a simple linear interpolation is
+ performed. With four arguments an extrapolation is also performed.
+ The exact values of arguments three and four are irrelevant, as
+ only there presence detremines whether interpolation and/or
+ extrapolation are used.
+
+
+
+
+# name: <cell-element>
+# type: sq_string
+# elements: 1
+# length: 80
+Using the lookup table created by "create_lookup_table", find the value
+Y corres
+
+
+
+
+