mirror of
https://github.com/Relintai/sdl2_frt.git
synced 2024-12-16 11:06:49 +01:00
526 lines
13 KiB
C
526 lines
13 KiB
C
/*
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Simple DirectMedia Layer
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Copyright (C) 1997-2016 Sam Lantinga <slouken@libsdl.org>
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This software is provided 'as-is', without any express or implied
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warranty. In no event will the authors be held liable for any damages
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arising from the use of this software.
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Permission is granted to anyone to use this software for any purpose,
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including commercial applications, and to alter it and redistribute it
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freely, subject to the following restrictions:
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1. The origin of this software must not be misrepresented; you must not
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claim that you wrote the original software. If you use this software
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in a product, an acknowledgment in the product documentation would be
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appreciated but is not required.
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2. Altered source versions must be plainly marked as such, and must not be
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misrepresented as being the original software.
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3. This notice may not be removed or altered from any source distribution.
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*/
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/*
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Data generators for fuzzing test data in a reproducible way.
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*/
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#include "SDL_config.h"
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/* Visual Studio 2008 doesn't have stdint.h */
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#if defined(_MSC_VER) && _MSC_VER <= 1500
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#define UINT8_MAX ~(Uint8)0
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#define UINT16_MAX ~(Uint16)0
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#define UINT32_MAX ~(Uint32)0
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#define UINT64_MAX ~(Uint64)0
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#else
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#define _GNU_SOURCE
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#include <stdint.h>
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#endif
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#include <stdio.h>
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#include <stdlib.h>
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#include <limits.h>
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#include <float.h>
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#include "SDL_test.h"
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/**
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* Counter for fuzzer invocations
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*/
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static int fuzzerInvocationCounter = 0;
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/**
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* Context for shared random number generator
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*/
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static SDLTest_RandomContext rndContext;
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/*
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* Note: doxygen documentation markup for functions is in the header file.
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*/
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void
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SDLTest_FuzzerInit(Uint64 execKey)
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{
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Uint32 a = (execKey >> 32) & 0x00000000FFFFFFFF;
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Uint32 b = execKey & 0x00000000FFFFFFFF;
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SDL_memset((void *)&rndContext, 0, sizeof(SDLTest_RandomContext));
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SDLTest_RandomInit(&rndContext, a, b);
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fuzzerInvocationCounter = 0;
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}
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int
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SDLTest_GetFuzzerInvocationCount()
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{
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return fuzzerInvocationCounter;
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}
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Uint8
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SDLTest_RandomUint8()
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{
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fuzzerInvocationCounter++;
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return (Uint8) SDLTest_RandomInt(&rndContext) & 0x000000FF;
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}
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Sint8
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SDLTest_RandomSint8()
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{
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fuzzerInvocationCounter++;
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return (Sint8) SDLTest_RandomInt(&rndContext) & 0x000000FF;
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}
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Uint16
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SDLTest_RandomUint16()
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{
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fuzzerInvocationCounter++;
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return (Uint16) SDLTest_RandomInt(&rndContext) & 0x0000FFFF;
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}
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Sint16
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SDLTest_RandomSint16()
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{
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fuzzerInvocationCounter++;
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return (Sint16) SDLTest_RandomInt(&rndContext) & 0x0000FFFF;
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}
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Sint32
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SDLTest_RandomSint32()
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{
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fuzzerInvocationCounter++;
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return (Sint32) SDLTest_RandomInt(&rndContext);
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}
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Uint32
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SDLTest_RandomUint32()
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{
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fuzzerInvocationCounter++;
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return (Uint32) SDLTest_RandomInt(&rndContext);
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}
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Uint64
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SDLTest_RandomUint64()
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{
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Uint64 value = 0;
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Uint32 *vp = (void *)&value;
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fuzzerInvocationCounter++;
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vp[0] = SDLTest_RandomSint32();
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vp[1] = SDLTest_RandomSint32();
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return value;
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}
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Sint64
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SDLTest_RandomSint64()
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{
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Uint64 value = 0;
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Uint32 *vp = (void *)&value;
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fuzzerInvocationCounter++;
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vp[0] = SDLTest_RandomSint32();
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vp[1] = SDLTest_RandomSint32();
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return value;
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}
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Sint32
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SDLTest_RandomIntegerInRange(Sint32 pMin, Sint32 pMax)
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{
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Sint64 min = pMin;
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Sint64 max = pMax;
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Sint64 temp;
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Sint64 number;
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if(pMin > pMax) {
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temp = min;
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min = max;
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max = temp;
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} else if(pMin == pMax) {
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return (Sint32)min;
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}
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number = SDLTest_RandomUint32();
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/* invocation count increment in preceeding call */
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return (Sint32)((number % ((max + 1) - min)) + min);
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}
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/* !
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* Generates a unsigned boundary value between the given boundaries.
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* Boundary values are inclusive. See the examples below.
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* If boundary2 < boundary1, the values are swapped.
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* If boundary1 == boundary2, value of boundary1 will be returned
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*
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* Generating boundary values for Uint8:
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* BoundaryValues(UINT8_MAX, 10, 20, True) -> [10,11,19,20]
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* BoundaryValues(UINT8_MAX, 10, 20, False) -> [9,21]
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* BoundaryValues(UINT8_MAX, 0, 15, True) -> [0, 1, 14, 15]
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* BoundaryValues(UINT8_MAX, 0, 15, False) -> [16]
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* BoundaryValues(UINT8_MAX, 0, 0xFF, False) -> [0], error set
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*
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* Generator works the same for other types of unsigned integers.
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*
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* \param maxValue The biggest value that is acceptable for this data type.
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* For instance, for Uint8 -> 255, Uint16 -> 65536 etc.
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* \param boundary1 defines lower boundary
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* \param boundary2 defines upper boundary
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* \param validDomain Generate only for valid domain (for the data type)
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*
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* \returns Returns a random boundary value for the domain or 0 in case of error
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*/
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Uint64
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SDLTest_GenerateUnsignedBoundaryValues(const Uint64 maxValue, Uint64 boundary1, Uint64 boundary2, SDL_bool validDomain)
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{
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Uint64 b1, b2;
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Uint64 delta;
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Uint64 tempBuf[4];
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Uint8 index;
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/* Maybe swap */
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if (boundary1 > boundary2) {
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b1 = boundary2;
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b2 = boundary1;
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} else {
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b1 = boundary1;
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b2 = boundary2;
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}
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index = 0;
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if (validDomain == SDL_TRUE) {
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if (b1 == b2) {
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return b1;
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}
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/* Generate up to 4 values within bounds */
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delta = b2 - b1;
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if (delta < 4) {
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do {
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tempBuf[index] = b1 + index;
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index++;
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} while (index < delta);
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} else {
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tempBuf[index] = b1;
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index++;
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tempBuf[index] = b1 + 1;
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index++;
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tempBuf[index] = b2 - 1;
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index++;
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tempBuf[index] = b2;
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index++;
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}
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} else {
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/* Generate up to 2 values outside of bounds */
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if (b1 > 0) {
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tempBuf[index] = b1 - 1;
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index++;
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}
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if (b2 < maxValue) {
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tempBuf[index] = b2 + 1;
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index++;
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}
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}
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if (index == 0) {
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/* There are no valid boundaries */
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SDL_Unsupported();
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return 0;
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}
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return tempBuf[SDLTest_RandomUint8() % index];
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}
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Uint8
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SDLTest_RandomUint8BoundaryValue(Uint8 boundary1, Uint8 boundary2, SDL_bool validDomain)
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{
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/* max value for Uint8 */
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const Uint64 maxValue = UCHAR_MAX;
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return (Uint8)SDLTest_GenerateUnsignedBoundaryValues(maxValue,
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(Uint64) boundary1, (Uint64) boundary2,
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validDomain);
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}
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Uint16
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SDLTest_RandomUint16BoundaryValue(Uint16 boundary1, Uint16 boundary2, SDL_bool validDomain)
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{
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/* max value for Uint16 */
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const Uint64 maxValue = USHRT_MAX;
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return (Uint16)SDLTest_GenerateUnsignedBoundaryValues(maxValue,
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(Uint64) boundary1, (Uint64) boundary2,
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validDomain);
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}
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Uint32
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SDLTest_RandomUint32BoundaryValue(Uint32 boundary1, Uint32 boundary2, SDL_bool validDomain)
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{
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/* max value for Uint32 */
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#if ((ULONG_MAX) == (UINT_MAX))
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const Uint64 maxValue = ULONG_MAX;
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#else
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const Uint64 maxValue = UINT_MAX;
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#endif
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return (Uint32)SDLTest_GenerateUnsignedBoundaryValues(maxValue,
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(Uint64) boundary1, (Uint64) boundary2,
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validDomain);
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}
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Uint64
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SDLTest_RandomUint64BoundaryValue(Uint64 boundary1, Uint64 boundary2, SDL_bool validDomain)
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{
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/* max value for Uint64 */
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const Uint64 maxValue = ULLONG_MAX;
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return SDLTest_GenerateUnsignedBoundaryValues(maxValue,
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(Uint64) boundary1, (Uint64) boundary2,
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validDomain);
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}
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/* !
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* Generates a signed boundary value between the given boundaries.
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* Boundary values are inclusive. See the examples below.
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* If boundary2 < boundary1, the values are swapped.
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* If boundary1 == boundary2, value of boundary1 will be returned
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*
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* Generating boundary values for Sint8:
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* SignedBoundaryValues(SCHAR_MIN, SCHAR_MAX, -10, 20, True) -> [-10,-9,19,20]
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* SignedBoundaryValues(SCHAR_MIN, SCHAR_MAX, -10, 20, False) -> [-11,21]
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* SignedBoundaryValues(SCHAR_MIN, SCHAR_MAX, -30, -15, True) -> [-30, -29, -16, -15]
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* SignedBoundaryValues(SCHAR_MIN, SCHAR_MAX, -127, 15, False) -> [16]
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* SignedBoundaryValues(SCHAR_MIN, SCHAR_MAX, -127, 127, False) -> [0], error set
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*
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* Generator works the same for other types of signed integers.
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*
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* \param minValue The smallest value that is acceptable for this data type.
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* For instance, for Uint8 -> -127, etc.
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* \param maxValue The biggest value that is acceptable for this data type.
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* For instance, for Uint8 -> 127, etc.
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* \param boundary1 defines lower boundary
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* \param boundary2 defines upper boundary
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* \param validDomain Generate only for valid domain (for the data type)
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*
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* \returns Returns a random boundary value for the domain or 0 in case of error
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*/
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Sint64
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SDLTest_GenerateSignedBoundaryValues(const Sint64 minValue, const Sint64 maxValue, Sint64 boundary1, Sint64 boundary2, SDL_bool validDomain)
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{
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Sint64 b1, b2;
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Sint64 delta;
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Sint64 tempBuf[4];
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Uint8 index;
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/* Maybe swap */
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if (boundary1 > boundary2) {
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b1 = boundary2;
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b2 = boundary1;
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} else {
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b1 = boundary1;
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b2 = boundary2;
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}
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index = 0;
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if (validDomain == SDL_TRUE) {
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if (b1 == b2) {
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return b1;
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}
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/* Generate up to 4 values within bounds */
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delta = b2 - b1;
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if (delta < 4) {
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do {
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tempBuf[index] = b1 + index;
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index++;
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} while (index < delta);
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} else {
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tempBuf[index] = b1;
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index++;
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tempBuf[index] = b1 + 1;
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index++;
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tempBuf[index] = b2 - 1;
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index++;
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tempBuf[index] = b2;
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index++;
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}
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} else {
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/* Generate up to 2 values outside of bounds */
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if (b1 > minValue) {
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tempBuf[index] = b1 - 1;
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index++;
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}
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if (b2 < maxValue) {
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tempBuf[index] = b2 + 1;
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index++;
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}
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}
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if (index == 0) {
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/* There are no valid boundaries */
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SDL_Unsupported();
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return minValue;
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}
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return tempBuf[SDLTest_RandomUint8() % index];
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}
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Sint8
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SDLTest_RandomSint8BoundaryValue(Sint8 boundary1, Sint8 boundary2, SDL_bool validDomain)
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{
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/* min & max values for Sint8 */
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const Sint64 maxValue = SCHAR_MAX;
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const Sint64 minValue = SCHAR_MIN;
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return (Sint8)SDLTest_GenerateSignedBoundaryValues(minValue, maxValue,
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(Sint64) boundary1, (Sint64) boundary2,
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validDomain);
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}
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Sint16
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SDLTest_RandomSint16BoundaryValue(Sint16 boundary1, Sint16 boundary2, SDL_bool validDomain)
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{
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/* min & max values for Sint16 */
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const Sint64 maxValue = SHRT_MAX;
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const Sint64 minValue = SHRT_MIN;
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return (Sint16)SDLTest_GenerateSignedBoundaryValues(minValue, maxValue,
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(Sint64) boundary1, (Sint64) boundary2,
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validDomain);
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}
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Sint32
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SDLTest_RandomSint32BoundaryValue(Sint32 boundary1, Sint32 boundary2, SDL_bool validDomain)
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{
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/* min & max values for Sint32 */
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#if ((ULONG_MAX) == (UINT_MAX))
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const Sint64 maxValue = LONG_MAX;
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const Sint64 minValue = LONG_MIN;
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#else
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const Sint64 maxValue = INT_MAX;
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const Sint64 minValue = INT_MIN;
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#endif
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return (Sint32)SDLTest_GenerateSignedBoundaryValues(minValue, maxValue,
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(Sint64) boundary1, (Sint64) boundary2,
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validDomain);
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}
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Sint64
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SDLTest_RandomSint64BoundaryValue(Sint64 boundary1, Sint64 boundary2, SDL_bool validDomain)
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{
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/* min & max values for Sint64 */
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const Sint64 maxValue = LLONG_MAX;
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const Sint64 minValue = LLONG_MIN;
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return SDLTest_GenerateSignedBoundaryValues(minValue, maxValue,
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boundary1, boundary2,
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validDomain);
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}
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float
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SDLTest_RandomUnitFloat()
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{
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return (float) SDLTest_RandomUint32() / UINT_MAX;
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}
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float
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SDLTest_RandomFloat()
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{
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return (float) (SDLTest_RandomUnitDouble() * (double)2.0 * (double)FLT_MAX - (double)(FLT_MAX));
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}
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double
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SDLTest_RandomUnitDouble()
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{
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return (double) (SDLTest_RandomUint64() >> 11) * (1.0/9007199254740992.0);
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}
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double
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SDLTest_RandomDouble()
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{
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double r = 0.0;
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double s = 1.0;
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do {
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s /= UINT_MAX + 1.0;
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r += (double)SDLTest_RandomInt(&rndContext) * s;
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} while (s > DBL_EPSILON);
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fuzzerInvocationCounter++;
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return r;
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}
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char *
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SDLTest_RandomAsciiString()
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{
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return SDLTest_RandomAsciiStringWithMaximumLength(255);
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}
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char *
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SDLTest_RandomAsciiStringWithMaximumLength(int maxLength)
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{
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int size;
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if(maxLength < 1) {
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SDL_InvalidParamError("maxLength");
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return NULL;
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}
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size = (SDLTest_RandomUint32() % (maxLength + 1));
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return SDLTest_RandomAsciiStringOfSize(size);
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}
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char *
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SDLTest_RandomAsciiStringOfSize(int size)
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{
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char *string;
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int counter;
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if(size < 1) {
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SDL_InvalidParamError("size");
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return NULL;
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}
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string = (char *)SDL_malloc((size + 1) * sizeof(char));
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if (string==NULL) {
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return NULL;
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}
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for(counter = 0; counter < size; ++counter) {
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string[counter] = (char)SDLTest_RandomIntegerInRange(32, 126);
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}
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string[counter] = '\0';
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fuzzerInvocationCounter++;
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return string;
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}
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