| #ifndef _ASM_LGUEST_USER |
| #define _ASM_LGUEST_USER |
| /* Everything the "lguest" userspace program needs to know. */ |
| /* They can register up to 32 arrays of lguest_dma. */ |
| #define LGUEST_MAX_DMA 32 |
| /* At most we can dma 16 lguest_dma in one op. */ |
| #define LGUEST_MAX_DMA_SECTIONS 16 |
| |
| /* How many devices? Assume each one wants up to two dma arrays per device. */ |
| #define LGUEST_MAX_DEVICES (LGUEST_MAX_DMA/2) |
| |
| /*D:200 |
| * Lguest I/O |
| * |
| * The lguest I/O mechanism is the only way Guests can talk to devices. There |
| * are two hypercalls involved: SEND_DMA for output and BIND_DMA for input. In |
| * each case, "struct lguest_dma" describes the buffer: this contains 16 |
| * addr/len pairs, and if there are fewer buffer elements the len array is |
| * terminated with a 0. |
| * |
| * I/O is organized by keys: BIND_DMA attaches buffers to a particular key, and |
| * SEND_DMA transfers to buffers bound to particular key. By convention, keys |
| * correspond to a physical address within the device's page. This means that |
| * devices will never accidentally end up with the same keys, and allows the |
| * Host use The Futex Trick (as we'll see later in our journey). |
| * |
| * SEND_DMA simply indicates a key to send to, and the physical address of the |
| * "struct lguest_dma" to send. The Host will write the number of bytes |
| * transferred into the "struct lguest_dma"'s used_len member. |
| * |
| * BIND_DMA indicates a key to bind to, a pointer to an array of "struct |
| * lguest_dma"s ready for receiving, the size of that array, and an interrupt |
| * to trigger when data is received. The Host will only allow transfers into |
| * buffers with a used_len of zero: it then sets used_len to the number of |
| * bytes transferred and triggers the interrupt for the Guest to process the |
| * new input. */ |
| struct lguest_dma |
| { |
| /* 0 if free to be used, filled by the Host. */ |
| u32 used_len; |
| unsigned long addr[LGUEST_MAX_DMA_SECTIONS]; |
| u16 len[LGUEST_MAX_DMA_SECTIONS]; |
| }; |
| /*:*/ |
| |
| /*D:460 This is the layout of a block device memory page. The Launcher sets up |
| * the num_sectors initially to tell the Guest the size of the disk. The Guest |
| * puts the type, sector and length of the request in the first three fields, |
| * then DMAs to the Host. The Host processes the request, sets up the result, |
| * then DMAs back to the Guest. */ |
| struct lguest_block_page |
| { |
| /* 0 is a read, 1 is a write. */ |
| int type; |
| u32 sector; /* Offset in device = sector * 512. */ |
| u32 bytes; /* Length expected to be read/written in bytes */ |
| /* 0 = pending, 1 = done, 2 = done, error */ |
| int result; |
| u32 num_sectors; /* Disk length = num_sectors * 512 */ |
| }; |
| |
| /*D:520 The network device is basically a memory page where all the Guests on |
| * the network publish their MAC (ethernet) addresses: it's an array of "struct |
| * lguest_net": */ |
| struct lguest_net |
| { |
| /* Simply the mac address (with multicast bit meaning promisc). */ |
| unsigned char mac[6]; |
| }; |
| /*:*/ |
| |
| /* Where the Host expects the Guest to SEND_DMA console output to. */ |
| #define LGUEST_CONSOLE_DMA_KEY 0 |
| |
| /*D:010 |
| * Drivers |
| * |
| * The Guest needs devices to do anything useful. Since we don't let it touch |
| * real devices (think of the damage it could do!) we provide virtual devices. |
| * We could emulate a PCI bus with various devices on it, but that is a fairly |
| * complex burden for the Host and suboptimal for the Guest, so we have our own |
| * "lguest" bus and simple drivers. |
| * |
| * Devices are described by an array of LGUEST_MAX_DEVICES of these structs, |
| * placed by the Launcher just above the top of physical memory: |
| */ |
| struct lguest_device_desc { |
| /* The device type: console, network, disk etc. */ |
| u16 type; |
| #define LGUEST_DEVICE_T_CONSOLE 1 |
| #define LGUEST_DEVICE_T_NET 2 |
| #define LGUEST_DEVICE_T_BLOCK 3 |
| |
| /* The specific features of this device: these depends on device type |
| * except for LGUEST_DEVICE_F_RANDOMNESS. */ |
| u16 features; |
| #define LGUEST_NET_F_NOCSUM 0x4000 /* Don't bother checksumming */ |
| #define LGUEST_DEVICE_F_RANDOMNESS 0x8000 /* IRQ is fairly random */ |
| |
| /* This is how the Guest reports status of the device: the Host can set |
| * LGUEST_DEVICE_S_REMOVED to indicate removal, but the rest are only |
| * ever manipulated by the Guest, and only ever set. */ |
| u16 status; |
| /* 256 and above are device specific. */ |
| #define LGUEST_DEVICE_S_ACKNOWLEDGE 1 /* We have seen device. */ |
| #define LGUEST_DEVICE_S_DRIVER 2 /* We have found a driver */ |
| #define LGUEST_DEVICE_S_DRIVER_OK 4 /* Driver says OK! */ |
| #define LGUEST_DEVICE_S_REMOVED 8 /* Device has gone away. */ |
| #define LGUEST_DEVICE_S_REMOVED_ACK 16 /* Driver has been told. */ |
| #define LGUEST_DEVICE_S_FAILED 128 /* Something actually failed */ |
| |
| /* Each device exists somewhere in Guest physical memory, over some |
| * number of pages. */ |
| u16 num_pages; |
| u32 pfn; |
| }; |
| /*:*/ |
| |
| /* Write command first word is a request. */ |
| enum lguest_req |
| { |
| LHREQ_INITIALIZE, /* + pfnlimit, pgdir, start, pageoffset */ |
| LHREQ_GETDMA, /* + addr (returns &lguest_dma, irq in ->used_len) */ |
| LHREQ_IRQ, /* + irq */ |
| LHREQ_BREAK, /* + on/off flag (on blocks until someone does off) */ |
| }; |
| #endif /* _ASM_LGUEST_USER */ |
