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Migrate full(X) to convert(Array, X) in tests outside of test/sparsed…
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…ir and test/linalg. Migrate `full` to `convert` in some documentation.
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Sacha0 committed Jul 15, 2016
1 parent 54ce2f6 commit 8bf1968
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2 changes: 1 addition & 1 deletion doc/manual/arrays.rst
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Expand Up @@ -831,7 +831,7 @@ reference.
+----------------------------------------+----------------------------------+--------------------------------------------+
| :func:`speye(n) <speye>` | :func:`eye(n) <eye>` | Creates a *n*-by-*n* identity matrix. |
+----------------------------------------+----------------------------------+--------------------------------------------+
| :func:`full(S) <full>` | :func:`sparse(A) <sparse>` | Interconverts between dense |
| :func:`convert(Array, S) <convert>` | :func:`sparse(A) <sparse>` | Interconverts between dense |
| | | and sparse formats. |
+----------------------------------------+----------------------------------+--------------------------------------------+
| :func:`sprand(m,n,d) <sprand>` | :func:`rand(m,n) <rand>` | Creates a *m*-by-*n* random matrix (of |
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12 changes: 6 additions & 6 deletions doc/stdlib/linalg.rst
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Expand Up @@ -110,7 +110,7 @@ Linear algebra functions in Julia are largely implemented by calling functions f

.. Docstring generated from Julia source
Constructs an upper (``isupper=true``\ ) or lower (``isupper=false``\ ) bidiagonal matrix using the given diagonal (``dv``\ ) and off-diagonal (``ev``\ ) vectors. The result is of type ``Bidiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`full`\ . ``ev``\ 's length must be one less than the length of ``dv``\ .
Constructs an upper (``isupper=true``\ ) or lower (``isupper=false``\ ) bidiagonal matrix using the given diagonal (``dv``\ ) and off-diagonal (``ev``\ ) vectors. The result is of type ``Bidiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`convert`\ . ``ev``\ 's length must be one less than the length of ``dv``\ .

**Example**

Expand All @@ -125,7 +125,7 @@ Linear algebra functions in Julia are largely implemented by calling functions f

.. Docstring generated from Julia source
Constructs an upper (``uplo='U'``\ ) or lower (``uplo='L'``\ ) bidiagonal matrix using the given diagonal (``dv``\ ) and off-diagonal (``ev``\ ) vectors. The result is of type ``Bidiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`full`\ . ``ev``\ 's length must be one less than the length of ``dv``\ .
Constructs an upper (``uplo='U'``\ ) or lower (``uplo='L'``\ ) bidiagonal matrix using the given diagonal (``dv``\ ) and off-diagonal (``ev``\ ) vectors. The result is of type ``Bidiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`convert`\ . ``ev``\ 's length must be one less than the length of ``dv``\ .

**Example**

Expand Down Expand Up @@ -154,13 +154,13 @@ Linear algebra functions in Julia are largely implemented by calling functions f

.. Docstring generated from Julia source
Construct a symmetric tridiagonal matrix from the diagonal and first sub/super-diagonal, respectively. The result is of type ``SymTridiagonal`` and provides efficient specialized eigensolvers, but may be converted into a regular matrix with :func:`full`\ .
Construct a symmetric tridiagonal matrix from the diagonal and first sub/super-diagonal, respectively. The result is of type ``SymTridiagonal`` and provides efficient specialized eigensolvers, but may be converted into a regular matrix with :func:`convert`\ .

.. function:: Tridiagonal(dl, d, du)

.. Docstring generated from Julia source
Construct a tridiagonal matrix from the first subdiagonal, diagonal, and first superdiagonal, respectively. The result is of type ``Tridiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`full`\ . The lengths of ``dl`` and ``du`` must be one less than the length of ``d``\ .
Construct a tridiagonal matrix from the first subdiagonal, diagonal, and first superdiagonal, respectively. The result is of type ``Tridiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`convert`\ . The lengths of ``dl`` and ``du`` must be one less than the length of ``d``\ .

.. function:: Symmetric(A, uplo=:U)

Expand Down Expand Up @@ -658,7 +658,7 @@ Linear algebra functions in Julia are largely implemented by calling functions f

.. Docstring generated from Julia source
Compute the Hessenberg decomposition of ``A`` and return a ``Hessenberg`` object. If ``F`` is the factorization object, the unitary matrix can be accessed with ``F[:Q]`` and the Hessenberg matrix with ``F[:H]``\ . When ``Q`` is extracted, the resulting type is the ``HessenbergQ`` object, and may be converted to a regular matrix with :func:`full`\ .
Compute the Hessenberg decomposition of ``A`` and return a ``Hessenberg`` object. If ``F`` is the factorization object, the unitary matrix can be accessed with ``F[:Q]`` and the Hessenberg matrix with ``F[:H]``\ . When ``Q`` is extracted, the resulting type is the ``HessenbergQ`` object, and may be converted to a regular matrix with :func:`convert`\ .

.. function:: hessfact!(A)

Expand Down Expand Up @@ -974,7 +974,7 @@ Linear algebra functions in Julia are largely implemented by calling functions f

.. Docstring generated from Julia source
Construct a tridiagonal matrix from the first subdiagonal, diagonal, and first superdiagonal, respectively. The result is of type ``Tridiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`full`\ . The lengths of ``dl`` and ``du`` must be one less than the length of ``d``\ .
Construct a tridiagonal matrix from the first subdiagonal, diagonal, and first superdiagonal, respectively. The result is of type ``Tridiagonal`` and provides efficient specialized linear solvers, but may be converted into a regular matrix with :func:`convert`\ . The lengths of ``dl`` and ``du`` must be one less than the length of ``d``\ .

.. function:: rank(M)

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2 changes: 1 addition & 1 deletion test/hashing.jl
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Expand Up @@ -89,7 +89,7 @@ end
x = sprand(10, 10, 0.5)
x[1] = 1
x.nzval[1] = 0
@test hash(x) == hash(full(x))
@test hash(x) == hash(convert(Array, x))

let a = QuoteNode(1), b = QuoteNode(1.0)
@test (hash(a)==hash(b)) == (a==b)
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2 changes: 1 addition & 1 deletion test/perf/threads/stockcorr/pstockcorr.jl
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Expand Up @@ -78,7 +78,7 @@ function pstockcorr(n)
SimulPriceB[1,:] = CurrentPrice[2]

## Generating the paths of stock prices by Geometric Brownian Motion
const UpperTriangle = full(chol(Corr)) # UpperTriangle Matrix by Cholesky decomposition
const UpperTriangle = convert(Array, chol(Corr)) # UpperTriangle Matrix by Cholesky decomposition

# Optimization: pre-allocate these for performance
# NOTE: the new GC will hopefully fix this, but currently GC time
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