1------------------------------------------------------------------------------ 2-- -- 3-- GNAT RUN-TIME LIBRARY (GNARL) COMPONENTS -- 4-- -- 5-- I N T E R F A C E S . V X W O R K S -- 6-- -- 7-- S p e c -- 8-- -- 9-- Copyright (C) 1999-2018, AdaCore -- 10-- -- 11-- GNAT is free software; you can redistribute it and/or modify it under -- 12-- terms of the GNU General Public License as published by the Free Soft- -- 13-- ware Foundation; either version 3, or (at your option) any later ver- -- 14-- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- 15-- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY -- 16-- or FITNESS FOR A PARTICULAR PURPOSE. -- 17-- -- 18-- As a special exception under Section 7 of GPL version 3, you are granted -- 19-- additional permissions described in the GCC Runtime Library Exception, -- 20-- version 3.1, as published by the Free Software Foundation. -- 21-- -- 22-- You should have received a copy of the GNU General Public License and -- 23-- a copy of the GCC Runtime Library Exception along with this program; -- 24-- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see -- 25-- <http://www.gnu.org/licenses/>. -- 26-- -- 27-- GNARL was developed by the GNARL team at Florida State University. -- 28-- Extensive contributions were provided by Ada Core Technologies, Inc. -- 29-- -- 30------------------------------------------------------------------------------ 31 32-- This is the x86 VxWorks version of this package 33 34-- This package provides a limited binding to the VxWorks API 35-- In particular, it interfaces with the VxWorks hardware interrupt 36-- facilities, allowing the use of low-latency direct-vectored 37-- interrupt handlers. Note that such handlers have a variety of 38-- restrictions regarding system calls and language constructs. In particular, 39-- the use of exception handlers and functions returning variable-length 40-- objects cannot be used. Less restrictive, but higher-latency handlers can 41-- be written using Ada protected procedures, Ada 83 style interrupt entries, 42-- or by signalling an Ada task from within an interrupt handler using a 43-- binary semaphore as described in the VxWorks Programmer's Manual. 44-- 45-- For complete documentation of the operations in this package, please 46-- consult the VxWorks Programmer's Manual and VxWorks Reference Manual. 47 48pragma Warnings (Off, "*foreign convention*"); 49pragma Warnings (Off, "*add Convention pragma*"); 50 51with System.VxWorks; 52 53package Interfaces.VxWorks is 54 pragma Preelaborate; 55 56 ------------------------------------------------------------------------ 57 -- Here is a complete example that shows how to handle the Interrupt 0x33 58 -- with a direct-vectored interrupt handler in Ada using this package: 59 60 -- with Interfaces.VxWorks; use Interfaces.VxWorks; 61 -- with System; 62 -- 63 -- package P is 64 -- 65 -- Count : Integer; 66 -- pragma Atomic (Count); 67 -- 68 -- procedure Handler (Parameter : System.Address); 69 -- 70 -- end P; 71 -- 72 -- package body P is 73 -- 74 -- procedure Handler (Parameter : System.Address) is 75 -- begin 76 -- Count := Count + 1; 77 -- logMsg ("received an interrupt" & ASCII.LF & ASCII.NUL); 78 -- end Handler; 79 -- end P; 80 -- 81 -- with Interfaces.VxWorks; use Interfaces.VxWorks; 82 -- with Ada.Text_IO; use Ada.Text_IO; 83 -- with Ada.Interrupts; 84 -- with Machine_Code; use Machine_Code; 85 -- 86 -- with P; use P; 87 -- procedure Useint is 88 -- 89 -- -- Be sure to use a reasonable interrupt number for target board. 90 -- -- This one is an unreserved interrupt for the Pentium 3 BSP 91 -- 92 -- Interrupt : constant := 16#33#; 93 -- 94 -- task T; 95 -- 96 -- S : STATUS; 97 -- 98 -- task body T is 99 -- begin 100 -- loop 101 -- Put_Line ("Generating an interrupt..."); 102 -- delay 1.0; 103 -- 104 -- -- Generate interrupt, using interrupt number 105 -- 106 -- Asm ("int %0", 107 -- Inputs => 108 -- Ada.Interrupts.Interrupt_ID'Asm_Input 109 -- ("i", Interrupt)); 110 -- end loop; 111 -- end T; 112 -- 113 -- begin 114 -- S := intConnect (INUM_TO_IVEC (Interrupt), Handler'Access); 115 -- 116 -- loop 117 -- delay 2.0; 118 -- Put_Line ("value of count:" & P.Count'Img); 119 -- end loop; 120 -- end Useint; 121 ------------------------------------- 122 123 subtype int is Integer; 124 125 type STATUS is new int; 126 -- Equivalent of the C type STATUS 127 128 OK : constant STATUS := 0; 129 ERROR : constant STATUS := -1; 130 131 type VOIDFUNCPTR is access procedure (parameter : System.Address); 132 type Interrupt_Vector is new System.Address; 133 type Exception_Vector is new System.Address; 134 135 function intConnect 136 (vector : Interrupt_Vector; 137 handler : VOIDFUNCPTR; 138 parameter : System.Address := System.Null_Address) return STATUS; 139 -- Binding to the C routine intConnect. Use this to set up an user handler. 140 -- The routine generates a wrapper around the user handler to save and 141 -- restore context 142 143 function intContext return int; 144 -- Binding to the C routine intContext. This function returns 1 only if the 145 -- current execution state is in interrupt context. 146 147 function intVecGet 148 (Vector : Interrupt_Vector) return VOIDFUNCPTR; 149 -- Binding to the C routine intVecGet. Use this to get the existing handler 150 -- for later restoral 151 152 procedure intVecSet 153 (Vector : Interrupt_Vector; 154 Handler : VOIDFUNCPTR); 155 -- Binding to the C routine intVecSet. Use this to restore a handler 156 -- obtained using intVecGet 157 158 procedure intVecGet2 159 (vector : Interrupt_Vector; 160 pFunction : out VOIDFUNCPTR; 161 pIdtGate : not null access int; 162 pIdtSelector : not null access int); 163 -- Binding to the C routine intVecGet2. Use this to get the existing 164 -- handler for later restoral 165 166 procedure intVecSet2 167 (vector : Interrupt_Vector; 168 pFunction : VOIDFUNCPTR; 169 pIdtGate : not null access int; 170 pIdtSelector : not null access int); 171 -- Binding to the C routine intVecSet2. Use this to restore a 172 -- handler obtained using intVecGet2 173 174 function INUM_TO_IVEC (intNum : int) return Interrupt_Vector; 175 -- Equivalent to the C macro INUM_TO_IVEC used to convert an interrupt 176 -- number to an interrupt vector 177 178 procedure logMsg 179 (fmt : String; arg1, arg2, arg3, arg4, arg5, arg6 : int := 0); 180 -- Binding to the C routine logMsg. Note that it is the caller's 181 -- responsibility to ensure that fmt is a null-terminated string 182 -- (e.g logMsg ("Interrupt" & ASCII.NUL)) 183 184 type FP_CONTEXT is private; 185 -- Floating point context save and restore. Handlers using floating point 186 -- must be bracketed with these calls. The pFpContext parameter should be 187 -- an object of type FP_CONTEXT that is declared local to the handler. 188 -- 189 -- See the VxWorks Intel Architecture Supplement regarding these routines 190 191 procedure fppRestore (pFpContext : in out FP_CONTEXT); 192 -- Restore floating point context - old style 193 194 procedure fppSave (pFpContext : in out FP_CONTEXT); 195 -- Save floating point context - old style 196 197 procedure fppXrestore (pFpContext : in out FP_CONTEXT); 198 -- Restore floating point context - new style 199 200 procedure fppXsave (pFpContext : in out FP_CONTEXT); 201 -- Save floating point context - new style 202 203private 204 205 type FP_CONTEXT is new System.VxWorks.FP_CONTEXT; 206 -- Target-dependent floating point context type 207 208 pragma Import (C, intConnect, "intConnect"); 209 pragma Import (C, intContext, "intContext"); 210 pragma Import (C, intVecGet, "intVecGet"); 211 pragma Import (C, intVecSet, "intVecSet"); 212 pragma Import (C, intVecGet2, "intVecGet2"); 213 pragma Import (C, intVecSet2, "intVecSet2"); 214 pragma Import (C, INUM_TO_IVEC, "__gnat_inum_to_ivec"); 215 pragma Import (C, logMsg, "logMsg"); 216 pragma Import (C, fppRestore, "fppRestore"); 217 pragma Import (C, fppSave, "fppSave"); 218 pragma Import (C, fppXrestore, "fppXrestore"); 219 pragma Import (C, fppXsave, "fppXsave"); 220end Interfaces.VxWorks; 221