qmckl/tools/lib.org

# -*- mode: org -*-

* Function to get the value of a property.
#+NAME: get_value
#+begin_src elisp :var key="Type"
(setq x (org-property-values key))
(pop x)
#+end_src

#+RESULTS: get_value

* Table of function arguments
  
  #+NAME: test
  | qmckl_context | context   | in  | Global state                                  |
  | char          | transa    | in  | Array ~A~ is ~'N'~: Normal, ~'T'~: Transposed |
  | char          | transb    | in  | Array ~B~ is ~'N'~: Normal, ~'T'~: Transposed |
  | int64_t       | m         | in  | Number of points in the first set             |
  | int64_t       | n         | in  | Number of points in the second set            |
  | double        | A[3][lda] | in  | Array containing the $m \times 3$ matrix $A$  |
  | int64_t       | lda       | in  | Leading dimension of array ~A~                |
  | double        | B[3][ldb] | in  | Array containing the $n \times 3$ matrix $B$  |
  | int64_t       | ldb       | in  | Leading dimension of array ~B~                |
  | double        | C[n][ldc] | out | Array containing the $m \times n$ matrix $C$  |
  | int64_t       | ldc       | in  | Leading dimension of array ~C~                |

  
** Fortran-C type conversions

   #+NAME:f_of_c
   #+BEGIN_SRC python :var table=test :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval f) :comments org :exports none"
f_of_c_d = { '' : ''
     , 'qmckl_context' : 'integer (c_int64_t)'
     , 'int32_t'       : 'integer (c_int32_t)'
     , 'int64_t'       : 'integer (c_int64_t)'
     , 'float'         : 'real    (c_float  )'
     , 'double'        : 'real    (c_double )'
     , 'char'          : 'character'
 }
   #+END_SRC
   
   #+NAME:c_of_f
   #+BEGIN_SRC python :var table=test :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval f) :comments org :exports none"
ctypeid_d = { '' : ''
     , 'integer'       : 'integer(c_int32_t)' 
     , 'integer*8'     : 'integer(c_int64_t)' 
     , 'real'          : 'real(c_float)'
     , 'real*8'        : 'real(c_double)'
     , 'character'     : 'character(c_char)'
 }
   #+END_SRC
   
** Parse the table

   #+NAME: parse_table
   #+BEGIN_SRC python :results none :noweb yes :exports none
def parse_table(table):
    result = []

    for line in table:
        d = { "c_type"  : line[0],
              "inout"   : line[2].lower(),
              "name"    : line[1],
              "comment" : line[3] }

        # Handle inout
        if d["inout"] in ["input", "in"]:
            d["inout"] == "in"
        elif d["inout"] in ["output", "out"]:
            d["inout"] == "out"
        elif d["inout"] in ["input/output", "inout"]:
            d["inout"] == "inout"

        # Find dimensions
        dims = d["name"].split('[')
        d["rank"] = len(dims) - 1
        if d["rank"] == 0:
            d["dims"] = []
        else:
            d["name"] = d["name"].split('[')[0].strip()
            d["dims"] = [ x.replace(']','').strip() for x in dims[1:] ]
        
        result.append(d)

    return result
   #+END_SRC

** Generates a C header

   #+NAME: generate_c_header
   #+BEGIN_SRC python :var table=[] :var rettyp=[] :var fname=[] :results drawer :noweb yes :wrap "src c :tangle (eval h) :comments org"
<<parse_table>>

results = []
for d in parse_table(table):
    name = d["name"]
    c_type = d["c_type"]

    # Add star for arrays
    if d["rank"] > 0:
        c_type += "*"

    # Only inputs are const
    if d["inout"] == "in":
        const = "const"
    else:
        const = "     "
    
    results += [ f"      {const} {c_type} {name}" ]

results=',\n'.join(results)
template = f"""{rettyp} {fname} (
{results} ); """
return template

   #+END_SRC

   #+RESULTS: generate_c_header
   #+begin_src c :tangle (eval h) :comments org
   [] [] (
    ); 
   #+end_src
   
** Generates a C interface to the Fortran function

   #+NAME: generate_c_interface
   #+BEGIN_SRC python :var table=[]   :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval f) :comments org :exports none"
<<c_of_f>>
<<f_of_c>>
<<parse_table>>
d = parse_table(table)

args = ", ".join([ x["name"] for x in d ])

rettyp_c = ctypeid_d[rettyp.lower()]

results = [ f"{rettyp_c} function {fname} &"
, f"    ({args}) &"
,  "    bind(C) result(info)"
,  ""            
,  "  use, intrinsic :: iso_c_binding"
,  "  implicit none"
,  ""
]

for d in parse_table(table):
    f_type = f_of_c_d[d["c_type"]]
    inout  = "intent("+d["inout"]+")"
    name = d["name"]

    # Input scalars are passed by value
    if d["rank"] == 0 and inout == "in":
        value = ", value"
    else:
        value = "       "

    # Append dimensions to the name
    if d["rank"] == 0:
        dims = ""
    else:
        d["dims"].reverse()
        dims = "(" + ",".join(d["dims"]) + ")"

    results += [ f"  {f_type:20}, {inout:12}{value} :: {name}{dims}" ]

results += [ ""
, f"  {rettyp_c}, external :: {fname}_f"
, f"  info = {fname}_f &"
, f"         ({args})" 
,  ""
, f"end function {fname}"
]
results='\n'.join(results)
return results
   #+END_SRC


** Generates a Fortran interface to the C function

   #+NAME: generate_f_interface
   #+BEGIN_SRC python :var table=test :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval fh) :comments org :exports none"
<<c_of_f>>
<<f_of_c>>
<<parse_table>>
d = parse_table(table)

args = ", ".join([ x["name"] for x in d ])

rettyp_c = ctypeid_d[rettyp.lower()]

results = [ f"interface"
, f"  {rettyp_c} function {fname} &"
, f"      ({args}) &"
,  "      bind(C)"
,  "    use, intrinsic :: iso_c_binding"
,  "    implicit none"
,  ""
]

for d in parse_table(table):
    f_type = f_of_c_d[d["c_type"]]
    inout  = "intent("+d["inout"]+")"
    name = d["name"]

    # Input scalars are passed by value
    if d["rank"] == 0 and inout == "in":
        value = ", value"
    else:
        value = "       "

    # Append dimensions to the name
    if d["rank"] == 0:
        dims = ""
    else:
        d["dims"].reverse()
        dims = "(" + ",".join(d["dims"]) + ")"

    results += [ f"    {f_type:20}, {inout:12}{value} :: {name}{dims}" ]

results += [ ""
, f"  end function {fname}"
, f"end interface"
]
results='\n'.join(results)
return results
   #+END_SRC

   #+RESULTS: generate_c_interface
   #+begin_src f90 :tangle (eval f) :comments org :exports none
   #+end_src
Included auto-generation of Fortran in distances 2021-03-20 16:56:22 +01:00			`# -- mode: org --`

			`* Function to get the value of a property.`
			`#+NAME: get_value`
			`#+begin_src elisp :var key="Type"`
			`(setq x (org-property-values key))`
			`(pop x)`
			`#+end_src`

			`#+RESULTS: get_value`

			`* Table of function arguments`

			`#+NAME: test`
			`\| qmckl_context \| context \| in \| Global state \|`
			`\| char \| transa \| in \| Array ~A~ is ~'N'~: Normal, ~'T'~: Transposed \|`
			`\| char \| transb \| in \| Array ~B~ is ~'N'~: Normal, ~'T'~: Transposed \|`
			`\| int64_t \| m \| in \| Number of points in the first set \|`
			`\| int64_t \| n \| in \| Number of points in the second set \|`
			`\| double \| A[3][lda] \| in \| Array containing the $m \times 3$ matrix $A$ \|`
			`\| int64_t \| lda \| in \| Leading dimension of array ~A~ \|`
			`\| double \| B[3][ldb] \| in \| Array containing the $n \times 3$ matrix $B$ \|`
			`\| int64_t \| ldb \| in \| Leading dimension of array ~B~ \|`
			`\| double \| C[n][ldc] \| out \| Array containing the $m \times n$ matrix $C$ \|`
			`\| int64_t \| ldc \| in \| Leading dimension of array ~C~ \|`


			`** Fortran-C type conversions`

			`#+NAME:f_of_c`
			`#+BEGIN_SRC python :var table=test :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval f) :comments org :exports none"`
			`f_of_c_d = { '' : ''`
			`, 'qmckl_context' : 'integer (c_int64_t)'`
			`, 'int32_t' : 'integer (c_int32_t)'`
			`, 'int64_t' : 'integer (c_int64_t)'`
			`, 'float' : 'real (c_float )'`
			`, 'double' : 'real (c_double )'`
			`, 'char' : 'character'`
			`}`
			`#+END_SRC`

			`#+NAME:c_of_f`
			`#+BEGIN_SRC python :var table=test :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval f) :comments org :exports none"`
			`ctypeid_d = { '' : ''`
			`, 'integer' : 'integer(c_int32_t)'`
			`, 'integer*8' : 'integer(c_int64_t)'`
			`, 'real' : 'real(c_float)'`
			`, 'real*8' : 'real(c_double)'`
			`, 'character' : 'character(c_char)'`
			`}`
			`#+END_SRC`

			`** Parse the table`

			`#+NAME: parse_table`
			`#+BEGIN_SRC python :results none :noweb yes :exports none`
			`def parse_table(table):`
			`result = []`

			`for line in table:`
			`d = { "c_type" : line[0],`
			`"inout" : line[2].lower(),`
			`"name" : line[1],`
			`"comment" : line[3] }`

			`# Handle inout`
			`if d["inout"] in ["input", "in"]:`
			`d["inout"] == "in"`
			`elif d["inout"] in ["output", "out"]:`
			`d["inout"] == "out"`
			`elif d["inout"] in ["input/output", "inout"]:`
			`d["inout"] == "inout"`

			`# Find dimensions`
			`dims = d["name"].split('[')`
			`d["rank"] = len(dims) - 1`
			`if d["rank"] == 0:`
			`d["dims"] = []`
			`else:`
			`d["name"] = d["name"].split('[')[0].strip()`
			`d["dims"] = [ x.replace(']','').strip() for x in dims[1:] ]`

			`result.append(d)`

			`return result`
			`#+END_SRC`

			`** Generates a C header`

			`#+NAME: generate_c_header`
			`#+BEGIN_SRC python :var table=[] :var rettyp=[] :var fname=[] :results drawer :noweb yes :wrap "src c :tangle (eval h) :comments org"`
			`<<parse_table>>`

			`results = []`
			`for d in parse_table(table):`
			`name = d["name"]`
			`c_type = d["c_type"]`

			`# Add star for arrays`
			`if d["rank"] > 0:`
			`c_type += "*"`

			`# Only inputs are const`
			`if d["inout"] == "in":`
			`const = "const"`
			`else:`
			`const = " "`

			`results += [ f" {const} {c_type} {name}" ]`

			`results=',\n'.join(results)`
			`template = f"""{rettyp} {fname} (`
			`{results} ); """`
			`return template`

			`#+END_SRC`

			`#+RESULTS: generate_c_header`
			`#+begin_src c :tangle (eval h) :comments org`
			`[] [] (`
			`);`
			`#+end_src`

			`** Generates a C interface to the Fortran function`

			`#+NAME: generate_c_interface`
			`#+BEGIN_SRC python :var table=[] :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval f) :comments org :exports none"`
			`<<c_of_f>>`
			`<<f_of_c>>`
			`<<parse_table>>`
			`d = parse_table(table)`

			`args = ", ".join([ x["name"] for x in d ])`

			`rettyp_c = ctypeid_d[rettyp.lower()]`

			`results = [ f"{rettyp_c} function {fname} &"`
			`, f" ({args}) &"`
			`, " bind(C) result(info)"`
			`, ""`
			`, " use, intrinsic :: iso_c_binding"`
			`, " implicit none"`
			`, ""`
			`]`

			`for d in parse_table(table):`
			`f_type = f_of_c_d[d["c_type"]]`
			`inout = "intent("+d["inout"]+")"`
			`name = d["name"]`

			`# Input scalars are passed by value`
			`if d["rank"] == 0 and inout == "in":`
			`value = ", value"`
			`else:`
			`value = " "`

			`# Append dimensions to the name`
			`if d["rank"] == 0:`
			`dims = ""`
			`else:`
			`d["dims"].reverse()`
			`dims = "(" + ",".join(d["dims"]) + ")"`

			`results += [ f" {f_type:20}, {inout:12}{value} :: {name}{dims}" ]`

			`results += [ ""`
			`, f" {rettyp_c}, external :: {fname}_f"`
			`, f" info = {fname}_f &"`
			`, f" ({args})"`
			`, ""`
			`, f"end function {fname}"`
			`]`
			`results='\n'.join(results)`
			`return results`
			`#+END_SRC`


			`** Generates a Fortran interface to the C function`

			`#+NAME: generate_f_interface`
			`#+BEGIN_SRC python :var table=test :var rettyp="integer" :var fname=[] :results value :noweb yes :wrap "src f90 :tangle (eval fh) :comments org :exports none"`
			`<<c_of_f>>`
			`<<f_of_c>>`
			`<<parse_table>>`
			`d = parse_table(table)`

			`args = ", ".join([ x["name"] for x in d ])`

			`rettyp_c = ctypeid_d[rettyp.lower()]`

			`results = [ f"interface"`
			`, f" {rettyp_c} function {fname} &"`
			`, f" ({args}) &"`
			`, " bind(C)"`
			`, " use, intrinsic :: iso_c_binding"`
			`, " implicit none"`
			`, ""`
			`]`

			`for d in parse_table(table):`
			`f_type = f_of_c_d[d["c_type"]]`
			`inout = "intent("+d["inout"]+")"`
			`name = d["name"]`

			`# Input scalars are passed by value`
			`if d["rank"] == 0 and inout == "in":`
			`value = ", value"`
			`else:`
			`value = " "`

			`# Append dimensions to the name`
			`if d["rank"] == 0:`
			`dims = ""`
			`else:`
			`d["dims"].reverse()`
			`dims = "(" + ",".join(d["dims"]) + ")"`

			`results += [ f" {f_type:20}, {inout:12}{value} :: {name}{dims}" ]`

			`results += [ ""`
			`, f" end function {fname}"`
			`, f"end interface"`
			`]`
			`results='\n'.join(results)`
			`return results`
			`#+END_SRC`

			`#+RESULTS: generate_c_interface`
			`#+begin_src f90 :tangle (eval f) :comments org :exports none`
			`#+end_src`