/* * QEMU low level functions * * Copyright (c) 2003 Fabrice Bellard * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include #include #include #include #include #include #include "cpu.h" #if defined(USE_KQEMU) #include "vl.h" #endif #if defined(__i386__) && !defined(CONFIG_SOFTMMU) && !defined(CONFIG_USER_ONLY) #include #include /* When not using soft mmu, libc independant functions are needed for the CPU core because it needs to use alternates stacks and libc/thread incompatibles settings */ #include #define QEMU_SYSCALL0(name) \ { \ long __res; \ __asm__ volatile ("int $0x80" \ : "=a" (__res) \ : "0" (__NR_##name)); \ return __res; \ } #define QEMU_SYSCALL1(name,arg1) \ { \ long __res; \ __asm__ volatile ("int $0x80" \ : "=a" (__res) \ : "0" (__NR_##name),"b" ((long)(arg1))); \ return __res; \ } #define QEMU_SYSCALL2(name,arg1,arg2) \ { \ long __res; \ __asm__ volatile ("int $0x80" \ : "=a" (__res) \ : "0" (__NR_##name),"b" ((long)(arg1)),"c" ((long)(arg2))); \ return __res; \ } #define QEMU_SYSCALL3(name,arg1,arg2,arg3) \ { \ long __res; \ __asm__ volatile ("int $0x80" \ : "=a" (__res) \ : "0" (__NR_##name),"b" ((long)(arg1)),"c" ((long)(arg2)), \ "d" ((long)(arg3))); \ return __res; \ } #define QEMU_SYSCALL4(name,arg1,arg2,arg3,arg4) \ { \ long __res; \ __asm__ volatile ("int $0x80" \ : "=a" (__res) \ : "0" (__NR_##name),"b" ((long)(arg1)),"c" ((long)(arg2)), \ "d" ((long)(arg3)),"S" ((long)(arg4))); \ return __res; \ } #define QEMU_SYSCALL5(name,arg1,arg2,arg3,arg4,arg5) \ { \ long __res; \ __asm__ volatile ("int $0x80" \ : "=a" (__res) \ : "0" (__NR_##name),"b" ((long)(arg1)),"c" ((long)(arg2)), \ "d" ((long)(arg3)),"S" ((long)(arg4)),"D" ((long)(arg5))); \ return __res; \ } #define QEMU_SYSCALL6(name,arg1,arg2,arg3,arg4,arg5,arg6) \ { \ long __res; \ __asm__ volatile ("push %%ebp ; movl %%eax,%%ebp ; movl %1,%%eax ; int $0x80 ; pop %%ebp" \ : "=a" (__res) \ : "i" (__NR_##name),"b" ((long)(arg1)),"c" ((long)(arg2)), \ "d" ((long)(arg3)),"S" ((long)(arg4)),"D" ((long)(arg5)), \ "0" ((long)(arg6))); \ return __res; \ } int qemu_write(int fd, const void *buf, size_t n) { QEMU_SYSCALL3(write, fd, buf, n); } /****************************************************************/ /* shmat replacement */ int qemu_ipc(int call, unsigned long first, unsigned long second, unsigned long third, void *ptr, unsigned long fifth) { QEMU_SYSCALL6(ipc, call, first, second, third, ptr, fifth); } #define SHMAT 21 /* we must define shmat so that a specific address will be used when mapping the X11 ximage */ void *shmat(int shmid, const void *shmaddr, int shmflg) { void *ptr; int ret; /* we give an address in the right memory area */ if (!shmaddr) shmaddr = get_mmap_addr(8192 * 1024); ret = qemu_ipc(SHMAT, shmid, shmflg, (unsigned long)&ptr, (void *)shmaddr, 0); if (ret < 0) return NULL; return ptr; } /****************************************************************/ /* sigaction bypassing the threads */ static int kernel_sigaction(int signum, const struct qemu_sigaction *act, struct qemu_sigaction *oldact, int sigsetsize) { QEMU_SYSCALL4(rt_sigaction, signum, act, oldact, sigsetsize); } int qemu_sigaction(int signum, const struct qemu_sigaction *act, struct qemu_sigaction *oldact) { return kernel_sigaction(signum, act, oldact, 8); } /****************************************************************/ /* memory allocation */ //#define DEBUG_MALLOC #define MALLOC_BASE 0xab000000 #define PHYS_RAM_BASE 0xac000000 #define MALLOC_ALIGN 16 #define BLOCK_HEADER_SIZE 16 typedef struct MemoryBlock { struct MemoryBlock *next; unsigned long size; /* size of block, including header */ } MemoryBlock; static MemoryBlock *first_free_block; static unsigned long malloc_addr = MALLOC_BASE; static void *malloc_get_space(size_t size) { void *ptr; size = TARGET_PAGE_ALIGN(size); ptr = mmap((void *)malloc_addr, size, PROT_WRITE | PROT_READ, MAP_PRIVATE | MAP_FIXED | MAP_ANON, -1, 0); if (ptr == MAP_FAILED) return NULL; malloc_addr += size; return ptr; } void *qemu_malloc(size_t size) { MemoryBlock *mb, *mb1, **pmb; void *ptr; size_t size1, area_size; if (size == 0) return NULL; size = (size + BLOCK_HEADER_SIZE + MALLOC_ALIGN - 1) & ~(MALLOC_ALIGN - 1); pmb = &first_free_block; for(;;) { mb = *pmb; if (mb == NULL) break; if (size <= mb->size) goto found; pmb = &mb->next; } /* no big enough blocks found: get new space */ area_size = TARGET_PAGE_ALIGN(size); mb = malloc_get_space(area_size); if (!mb) return NULL; size1 = area_size - size; if (size1 > 0) { /* create a new free block */ mb1 = (MemoryBlock *)((uint8_t *)mb + size); mb1->next = NULL; mb1->size = size1; *pmb = mb1; } goto the_end; found: /* a free block was found: use it */ size1 = mb->size - size; if (size1 > 0) { /* create a new free block */ mb1 = (MemoryBlock *)((uint8_t *)mb + size); mb1->next = mb->next; mb1->size = size1; *pmb = mb1; } else { /* suppress the first block */ *pmb = mb->next; } the_end: mb->size = size; mb->next = NULL; ptr = ((uint8_t *)mb + BLOCK_HEADER_SIZE); #ifdef DEBUG_MALLOC qemu_printf("malloc: size=0x%x ptr=0x%lx\n", size, (unsigned long)ptr); #endif return ptr; } void qemu_free(void *ptr) { MemoryBlock *mb; if (!ptr) return; mb = (MemoryBlock *)((uint8_t *)ptr - BLOCK_HEADER_SIZE); mb->next = first_free_block; first_free_block = mb; } /****************************************************************/ /* virtual memory allocation */ unsigned long mmap_addr = PHYS_RAM_BASE; void *get_mmap_addr(unsigned long size) { unsigned long addr; addr = mmap_addr; mmap_addr += ((size + 4095) & ~4095) + 4096; return (void *)addr; } #else #ifdef _WIN32 #include #elif defined(_BSD) #include #else #include #endif int qemu_write(int fd, const void *buf, size_t n) { int ret; ret = write(fd, buf, n); if (ret < 0) return -errno; else return ret; } void *get_mmap_addr(unsigned long size) { return NULL; } void qemu_free(void *ptr) { free(ptr); } void *qemu_malloc(size_t size) { return malloc(size); } #if defined(_WIN32) void *qemu_vmalloc(size_t size) { /* FIXME: this is not exactly optimal solution since VirtualAlloc has 64Kb granularity, but at least it guarantees us that the memory is page aligned. */ return VirtualAlloc(NULL, size, MEM_COMMIT, PAGE_READWRITE); } void qemu_vfree(void *ptr) { VirtualFree(ptr, 0, MEM_RELEASE); } #else #if defined(USE_KQEMU) #include #include #include void *kqemu_vmalloc(size_t size) { static int phys_ram_fd = -1; static int phys_ram_size = 0; const char *tmpdir; char phys_ram_file[1024]; void *ptr; struct statfs stfs; if (phys_ram_fd < 0) { tmpdir = getenv("QEMU_TMPDIR"); if (!tmpdir) tmpdir = "/dev/shm"; if (statfs(tmpdir, &stfs) == 0) { int64_t free_space; int ram_mb; extern int ram_size; free_space = (int64_t)stfs.f_bavail * stfs.f_bsize; if ((ram_size + 8192 * 1024) >= free_space) { ram_mb = (ram_size / (1024 * 1024)); fprintf(stderr, 
/*
             LUFA Library
     Copyright (C) Dean Camera, 2017.

  dean [at] fourwalledcubicle [dot] com
           www.lufa-lib.org
*/

/*
  Copyright 2017  Dean Camera (dean [at] fourwalledcubicle [dot] com)

  Permission to use, copy, modify, distribute, and sell this
  software and its documentation for any purpose is hereby granted
  without fee, provided that the above copyright notice appear in
  all copies and that both that the copyright notice and this
  permission notice and warranty disclaimer appear in supporting
  documentation, and that the name of the author not be used in
  advertising or publicity pertaining to distribution of the
  software without specific, written prior permission.

  The author disclaims all warranties with regard to this
  software, including all implied warranties of merchantability
  and fitness.  In no event shall the author be liable for any
  special, indirect or consequential damages or any damages
  whatsoever resulting from loss of use, data or profits, whether
  in an action of contract, negligence or other tortious action,
  arising out of or in connection with the use or performance of
  this software.
*/

/** \file
 *
 *  Main source file for the AVRISP project. This file contains the main tasks of
 *  the project and is responsible for the initial application hardware configuration.
 */

#include "AVRISP-MKII.h"

#if (BOARD != BOARD_NONE)
  /* Some board hardware definitions (e.g. the Arduino Micro) have their LEDs defined on the same pins
     as the ISP, PDI or TPI interfaces (see the accompanying project documentation). If a board other
     than NONE is selected (to enable the LED driver with the programmer) you should double-check that
     no conflicts will occur. If there is a conflict, turn off the LEDs (set BOARD to NONE in the makefile)
     or define a custom board driver (see the LUFA manual) with alternative LED mappings.
  */
  #warning Board specific drivers have been selected; make sure the board LED driver does not conflict with the programmer ISP/PDI/TPI interfaces.
#endif

/** Main program entry point. This routine contains the overall program flow, including initial
 *  setup of all components and the main program loop.
 */
int main(void)
{
	SetupHardware();
	V2Protocol_Init();

	LEDs_SetAllLEDs(LEDMASK_USB_NOTREADY);
	GlobalInterruptEnable();

	for (;;)
	{
		#if (BOARD == BOARD_USBTINYMKII)
		/* On the USBTINY-MKII target, there is a secondary LED which indicates the current selected power
		   mode - either VBUS, or sourced from the VTARGET pin of the programming connectors */
		LEDs_ChangeLEDs(LEDMASK_VBUSPOWER, (PIND & (1 << 0)) ? 0 : LEDMASK_VBUSPOWER);
		#endif

		AVRISP_Task();
		USB_USBTask();
	}
}

/** Configures the board hardware and chip peripherals for the demo's functionality. */
void SetupHardware(void)
{
#if (ARCH == ARCH_AVR8)
	/* Disable watchdog if enabled by bootloader/fuses */
	MCUSR &= ~(1 << WDRF);
	wdt_disable();

	/* Disable clock division */
	clock_prescale_set(clock_div_1);
#endif

	/* Hardware Initialization */
	LEDs_Init();
	#if defined(RESET_TOGGLES_LIBUSB_COMPAT)
	UpdateCurrentCompatibilityMode();
	#endif

	/* USB Stack Initialization */
	USB_Init();
}

/** Event handler for the library USB Connection event. */
void EVENT_USB_Device_Connect(void)
{
	LEDs_SetAllLEDs(LEDMASK_USB_ENUMERATING);
}

/** Event handler for the library USB Disconnection event. */
void EVENT_USB_Device_Disconnect(void)
{
	LEDs_SetAllLEDs(LEDMASK_USB_NOTREADY);
}

/** Event handler for the library USB Configuration Changed event. */
void EVENT_USB_Device_ConfigurationChanged(void)
{
	bool ConfigSuccess = true;

	/* Setup AVRISP Data OUT endpoint */
	ConfigSuccess &= Endpoint_ConfigureEndpoint(AVRISP_DATA_OUT_EPADDR, EP_TYPE_BULK, AVRISP_DATA_EPSIZE, 1);

	/* Setup AVRISP Data IN endpoint if it is using a physically different endpoint */
	if ((AVRISP_DATA_IN_EPADDR & ENDPOINT_EPNUM_MASK) != (AVRISP_DATA_OUT_EPADDR & ENDPOINT_EPNUM_MASK))
	  ConfigSuccess &= Endpoint_ConfigureEndpoint(AVRISP_DATA_IN_EPADDR, EP_TYPE_BULK, AVRISP_DATA_EPSIZE, 1);

	/* Indicate endpoint configuration success or failure */
	LEDs_SetAllLEDs(ConfigSuccess ? LEDMASK_USB_READY : LEDMASK_USB_ERROR);
}

/** Processes incoming V2 Protocol commands from the host, returning a response when required. */
void AVRISP_Task(void)
{
	/* Device must be connected and configured for the task to run */
	if (USB_DeviceState != DEVICE_STATE_Configured)
	  return;

	V2Params_UpdateParamValues();

	Endpoint_SelectEndpoint(AVRISP_DATA_OUT_EPADDR);

	/* Check to see if a V2 Protocol command has been received */
	if (Endpoint_IsOUTReceived())
	{
		LEDs_SetAllLEDs(LEDMASK_BUSY);

		/* Pass off processing of the V2 Protocol command to the V2 Protocol handler */
		V2Protocol_ProcessCommand();

		LEDs_SetAllLEDs(LEDMASK_USB_READY);
	}
}

/** This function is called by the library when in device mode, and must be overridden (see library "USB Descriptors"
 *  documentation) by the application code so that the address and size of a requested descriptor can be given
 *  to the USB library. When the device receives a Get Descriptor request on the control endpoint, this function
 *  is called so that the descriptor details can be passed back and the appropriate descriptor sent back to the
 *  USB host.
 *
 *  \param[in]  wValue                 Descriptor type and index to retrieve
 *  \param[in]  wIndex                 Sub-index to retrieve (such as a localized string language)
 *  \param[out] DescriptorAddress      Address of the retrieved descriptor
 *
 *  \return Length of the retrieved descriptor in bytes, or NO_DESCRIPTOR if the descriptor was not found
 */
uint16_t CALLBACK_USB_GetDescriptor(const uint16_t wValue,
                                    const uint16_t wIndex,
                                    const void** const DescriptorAddress)
{
	return AVRISP_GetDescriptor(wValue, wIndex, DescriptorAddress);
}
generated by cgit v1.2.3 (git 2.25.1) at 2025-10-29 04:21:16 +0000