/* initialise our runtime environment */
static void
init_env(env_t env)
{
allocman_t *allocman;
UNUSED reservation_t virtual_reservation;
UNUSED int error;
/* create an allocator */
allocman = bootstrap_use_current_simple(&env->simple, ALLOCATOR_STATIC_POOL_SIZE, allocator_mem_pool);
assert(allocman);
/* create a vka (interface for interacting with the underlying allocator) */
allocman_make_vka(&env->vka, allocman);
/* create a vspace (virtual memory management interface). We pass
* boot info not because it will use capabilities from it, but so
* it knows the address and will add it as a reserved region */
error = sel4utils_bootstrap_vspace_with_bootinfo_leaky(&env->vspace,
&data, simple_get_pd(&env->simple), &env->vka, seL4_GetBootInfo());
/* fill the allocator with virtual memory */
void *vaddr;
virtual_reservation = vspace_reserve_range(&env->vspace,
ALLOCATOR_VIRTUAL_POOL_SIZE, seL4_AllRights, 1, &vaddr);
assert(virtual_reservation.res);
bootstrap_configure_virtual_pool(allocman, vaddr,
ALLOCATOR_VIRTUAL_POOL_SIZE, simple_get_pd(&env->simple));
}
static void make_proxy_vka(vka_t *vka, allocman_t *allocman) {
int num = ram_num_untypeds();
int error UNUSED;
proxy_vka_t *proxy = &proxy_vka;
memset(proxy, 0, sizeof(*proxy));
proxy->allocman = allocman;
allocman_make_vka(&proxy->regular_vka, allocman);
utspace_trickle_create(&proxy->ram_ut_manager);
for (int i = 0; i < num; i++) {
cspacepath_t path;
seL4_CPtr cap;
uintptr_t paddr;
int size_bits;
ram_get_untyped(i, &paddr, &size_bits, &cap);
vka_cspace_make_path(&proxy->regular_vka, cap, &path);
error = _utspace_trickle_add_uts(allocman, &proxy->ram_ut_manager, 1, &path, (uint32_t*)&size_bits, &paddr);
assert(!error);
}
if (num > 0) {
proxy->have_mem = 1;
}
*vka = (vka_t) {
proxy,
proxy_vka_cspace_alloc,
proxy_vka_cspace_make_path,
proxy_vka_utspace_alloc,
proxy_vka_cspace_free,
proxy_vka_utspace_free,
proxy_vka_utspace_paddr
};
}
/*
* Initialize all main data structures.
*
* The code to initialize simple, allocman, vka, and vspace is modeled
* after the "sel4test-driver" app:
* https://github.com/seL4/sel4test/blob/master/apps/sel4test-driver/src/main.c
*/
static void
setup_system()
{
/* initialize boot information */
bootinfo = seL4_GetBootInfo();
/* initialize simple interface */
simple_stable_init_bootinfo(&simple, bootinfo);
//simple_default_init_bootinfo(simple, bootinfo);
/* create an allocator */
allocman_t *allocman;
allocman = bootstrap_use_current_simple(&simple, POOL_SIZE, memPool);
assert(allocman);
/* create a VKA */
allocman_make_vka(&vka, allocman);
/* create a vspace */
UNUSED int err;
err = sel4utils_bootstrap_vspace_with_bootinfo_leaky(&vspace,
&allocData, seL4_CapInitThreadPD, &vka, bootinfo);
assert(err == 0);
/* fill allocator with virtual memory */
void *vaddr;
UNUSED reservation_t vres;
vres = vspace_reserve_range(&vspace, VIRT_POOL_SIZE, seL4_AllRights,
1, &vaddr);
assert(vres.res);
bootstrap_configure_virtual_pool(allocman, vaddr, VIRT_POOL_SIZE,
seL4_CapInitThreadPD);
}
static void
init_allocator(env_t env, test_init_data_t *init_data)
{
UNUSED int error;
UNUSED reservation_t virtual_reservation;
/* initialise allocator */
allocman_t *allocator = bootstrap_use_current_1level(init_data->root_cnode,
init_data->cspace_size_bits, init_data->free_slots.start,
init_data->free_slots.end, ALLOCATOR_STATIC_POOL_SIZE,
allocator_mem_pool);
if (allocator == NULL) {
ZF_LOGF("Failed to bootstrap allocator");
}
allocman_make_vka(&env->vka, allocator);
/* fill the allocator with untypeds */
seL4_CPtr slot;
unsigned int size_bits_index;
for (slot = init_data->untypeds.start, size_bits_index = 0;
slot <= init_data->untypeds.end;
slot++, size_bits_index++) {
cspacepath_t path;
vka_cspace_make_path(&env->vka, slot, &path);
/* allocman doesn't require the paddr unless we need to ask for phys addresses,
* which we don't. */
uintptr_t fake_paddr = 0;
size_t size_bits = init_data->untyped_size_bits_list[size_bits_index];
error = allocman_utspace_add_uts(allocator, 1, &path, &size_bits, &fake_paddr);
if (error) {
ZF_LOGF("Failed to add untyped objects to allocator");
}
}
/* create a vspace */
void *existing_frames[init_data->stack_pages + 2];
existing_frames[0] = (void *) init_data;
existing_frames[1] = seL4_GetIPCBuffer();
assert(init_data->stack_pages > 0);
for (int i = 0; i < init_data->stack_pages; i++) {
existing_frames[i + 2] = init_data->stack + (i * PAGE_SIZE_4K);
}
error = sel4utils_bootstrap_vspace(&env->vspace, &alloc_data, init_data->page_directory, &env->vka, NULL, NULL, existing_frames);
/* switch the allocator to a virtual memory pool */
void *vaddr;
virtual_reservation = vspace_reserve_range(&env->vspace, ALLOCATOR_VIRTUAL_POOL_SIZE,
seL4_AllRights, 1, &vaddr);
if (virtual_reservation.res == 0) {
ZF_LOGF("Failed to switch allocator to virtual memory pool");
}
bootstrap_configure_virtual_pool(allocator, vaddr, ALLOCATOR_VIRTUAL_POOL_SIZE,
env->page_directory);
}
allocman_t *test_use_current_cspace_bootinfo() {
int error;
allocman_t *allocman;
vspace_alloc_t vspace;
vka_t *vka;
allocman = bootstrap_use_bootinfo(seL4_GetBootInfo(), sizeof(initial_mem_pool), initial_mem_pool);
assert(allocman);
vka = allocman_mspace_alloc(allocman, sizeof(*vka), &error);
assert(!error);
allocman_make_vka(vka, allocman);
sel4util_get_vspace_alloc_leaky(&vspace, seL4_CapInitThreadPD, vka, seL4_GetBootInfo());
reservation_t *reservation = vspace_reserve_range_at(&vspace, VIRTUAL_START, MEM_POOL_SIZE, seL4_AllRights, 1);
assert(reservation);
bootstrap_configure_virtual_pool(allocman, VIRTUAL_START, MEM_POOL_SIZE, seL4_CapInitThreadPD);
error = allocman_fill_reserves(allocman);
assert(!error);
return allocman;
}
int main(void)
{
UNUSED int error;
/* Set up logging and give us a name: useful for debugging if the thread faults */
zf_log_set_tag_prefix("hello-3:");
name_thread(seL4_CapInitThreadTCB, "hello-3");
/* get boot info */
info = seL4_GetBootInfo();
/* init simple */
simple_default_init_bootinfo(&simple, info);
/* print out bootinfo and other info about simple */
simple_print(&simple);
/* create an allocator */
allocman = bootstrap_use_current_simple(&simple, ALLOCATOR_STATIC_POOL_SIZE, allocator_mem_pool);
ZF_LOGF_IF(allocman == NULL, "Failed to initialize alloc manager.\n"
"\tMemory pool sufficiently sized?\n"
"\tMemory pool pointer valid?\n");
/* create a vka (interface for interacting with the underlying allocator) */
allocman_make_vka(&vka, allocman);
/* get our cspace root cnode */
seL4_CPtr cspace_cap;
cspace_cap = simple_get_cnode(&simple);
/* get our vspace root page directory */
seL4_CPtr pd_cap;
pd_cap = simple_get_pd(&simple);
/* create a new TCB */
vka_object_t tcb_object = {0};
error = vka_alloc_tcb(&vka, &tcb_object);
ZF_LOGF_IFERR(error, "Failed to allocate new TCB.\n"
"\tVKA given sufficient bootstrap memory?");
/*
* create and map an ipc buffer:
*/
/* TODO 1: get a frame cap for the ipc buffer */
/* hint: vka_alloc_frame()
* int vka_alloc_frame(vka_t *vka, uint32_t size_bits, vka_object_t *result)
* @param vka Pointer to vka interface.
* @param size_bits Frame size: 2^size_bits
* @param result Structure for the Frame object. This gets initialised.
* @return 0 on success
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_1:
*/
vka_object_t ipc_frame_object;
error = vka_alloc_frame(&vka, IPCBUF_FRAME_SIZE_BITS, &ipc_frame_object);
ZF_LOGF_IFERR(error, "Failed to alloc a frame for the IPC buffer.\n"
"\tThe frame size is not the number of bytes, but an exponent.\n"
"\tNB: This frame is not an immediately usable, virtually mapped page.\n")
/*
* map the frame into the vspace at ipc_buffer_vaddr.
* To do this we first try to map it in to the root page directory.
* If there is already a page table mapped in the appropriate slot in the
* page diretory where we can insert this frame, then this will succeed.
* Otherwise we first need to create a page table, and map it in to
* the page directory, before we can map the frame in. */
seL4_Word ipc_buffer_vaddr = IPCBUF_VADDR;
/* TODO 2: try to map the frame the first time */
/* hint 1: seL4_ARCH_Page_Map()
* The *ARCH* versions of seL4 sys calls are abstractions over the architecture provided by libsel4utils
* this one is defined as:
* #define seL4_ARCH_Page_Map seL4_X86_Page_Map
* in: Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_2:
* The signature for the underlying function is:
* int seL4_X86_Page_Map(seL4_X86_Page service, seL4_X86_PageDirectory pd, seL4_Word vaddr, seL4_CapRights rights, seL4_X86_VMAttributes attr)
* @param service Capability to the page to map.
* @param pd Capability to the VSpace which will contain the mapping.
* @param vaddr Virtual address to map the page into.
* @param rights Rights for the mapping.
* @param attr VM Attributes for the mapping.
* @return 0 on success.
*
* Note: this function is generated during build. It is generated from the following definition:
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_2:
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*
* hint 2: for the rights, use seL4_AllRights
* hint 3: for VM attributes use seL4_ARCH_Default_VMAttributes
* Hint 4: It is normal for this function call to fail. That means there are
* no page tables with free slots -- proceed to the next step where you'll
* be led to allocate a new empty page table and map it into the VSpace,
* before trying again.
*/
error = seL4_ARCH_Page_Map(ipc_frame_object.cptr, pd_cap, ipc_buffer_vaddr,
seL4_AllRights, seL4_ARCH_Default_VMAttributes);
if (error != 0) {
/* TODO 3: create a page table */
/* hint: vka_alloc_page_table()
* int vka_alloc_page_table(vka_t *vka, vka_object_t *result)
* @param vka Pointer to vka interface.
* @param result Structure for the PageTable object. This gets initialised.
* @return 0 on success
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_3:
*/
vka_object_t pt_object;
error = vka_alloc_page_table(&vka, &pt_object);
ZF_LOGF_IFERR(error, "Failed to allocate new page table.\n");
/* TODO 4: map the page table */
/* hint 1: seL4_ARCH_PageTable_Map()
* The *ARCH* versions of seL4 sys calls are abstractions over the architecture provided by libsel4utils
* this one is defined as:
* #define seL4_ARCH_PageTable_Map seL4_X86_PageTable_Map
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_4:
* The signature for the underlying function is:
* int seL4_X86_PageTable_Map(seL4_X86_PageTable service, seL4_X86_PageDirectory pd, seL4_Word vaddr, seL4_X86_VMAttributes attr)
* @param service Capability to the page table to map.
* @param pd Capability to the VSpace which will contain the mapping.
* @param vaddr Virtual address to map the page table into.
* @param rights Rights for the mapping.
* @param attr VM Attributes for the mapping.
* @return 0 on success.
*
* Note: this function is generated during build. It is generated from the following definition:
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_4:
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*
* hint 2: for VM attributes use seL4_ARCH_Default_VMAttributes
*/
error = seL4_ARCH_PageTable_Map(pt_object.cptr, pd_cap,
ipc_buffer_vaddr, seL4_ARCH_Default_VMAttributes);
ZF_LOGF_IFERR(error, "Failed to map page table into VSpace.\n"
"\tWe are inserting a new page table into the top-level table.\n"
"\tPass a capability to the new page table, and not for example, the IPC buffer frame vaddr.\n")
/* TODO 5: then map the frame in */
/* hint 1: use seL4_ARCH_Page_Map() as above
* hint 2: for the rights, use seL4_AllRights
* hint 3: for VM attributes use seL4_ARCH_Default_VMAttributes
*/
error = seL4_ARCH_Page_Map(ipc_frame_object.cptr, pd_cap,
ipc_buffer_vaddr, seL4_AllRights, seL4_ARCH_Default_VMAttributes);
ZF_LOGF_IFERR(error, "Failed again to map the IPC buffer frame into the VSpace.\n"
"\t(It's not supposed to fail.)\n"
"\tPass a capability to the IPC buffer's physical frame.\n"
"\tRevisit the first seL4_ARCH_Page_Map call above and double-check your arguments.\n");
}
/* set the IPC buffer's virtual address in a field of the IPC buffer */
seL4_IPCBuffer *ipcbuf = (seL4_IPCBuffer*)ipc_buffer_vaddr;
ipcbuf->userData = ipc_buffer_vaddr;
/* TODO 6: create an endpoint */
/* hint: vka_alloc_endpoint()
* int vka_alloc_endpoint(vka_t *vka, vka_object_t *result)
* @param vka Pointer to vka interface.
* @param result Structure for the Endpoint object. This gets initialised.
* @return 0 on success
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_6:
*/
error = vka_alloc_endpoint(&vka, &ep_object);
ZF_LOGF_IFERR(error, "Failed to allocate new endpoint object.\n");
/* TODO 7: make a badged copy of it in our cspace. This copy will be used to send
* an IPC message to the original cap */
/* hint 1: vka_mint_object()
* int vka_mint_object(vka_t *vka, vka_object_t *object, cspacepath_t *result, seL4_CapRights rights, seL4_CapData_t badge)
* @param[in] vka The allocator for the cspace.
* @param[in] object Target object for cap minting.
* @param[out] result Allocated cspacepath.
* @param[in] rights The rights for the minted cap.
* @param[in] badge The badge for the minted cap.
* @return 0 on success
*
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_7:
*
* hint 2: for the rights, use seL4_AllRights
* hint 3: for the badge use seL4_CapData_Badge_new()
* seL4_CapData_t CONST seL4_CapData_Badge_new(seL4_Uint32 Badge)
* @param[in] Badge The badge number to use
* @return A CapData structure containing the desired badge info
*
* seL4_CapData_t is generated during build.
* The type definition and generated field access functions are defined in a generated file:
* build/x86/pc99/libsel4/include/sel4/types_gen.h
* It is generated from the following definition:
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_7:
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*
* hint 4: for the badge use EP_BADGE
*/
error = vka_mint_object(&vka, &ep_object, &ep_cap_path, seL4_AllRights,
seL4_CapData_Badge_new(EP_BADGE));
ZF_LOGF_IFERR(error, "Failed to mint new badged copy of IPC endpoint.\n"
"\tseL4_Mint is the backend for vka_mint_object.\n"
"\tseL4_Mint is simply being used here to create a badged copy of the same IPC endpoint.\n"
"\tThink of a badge in this case as an IPC context cookie.\n");
/* initialise the new TCB */
error = seL4_TCB_Configure(tcb_object.cptr, seL4_CapNull, seL4_PrioProps_new(seL4_MaxPrio, seL4_MaxPrio),
cspace_cap, seL4_NilData, pd_cap, seL4_NilData,
ipc_buffer_vaddr, ipc_frame_object.cptr);
ZF_LOGF_IFERR(error, "Failed to configure the new TCB object.\n"
"\tWe're running the new thread with the root thread's CSpace.\n"
"\tWe're running the new thread in the root thread's VSpace.\n");
/* give the new thread a name */
name_thread(tcb_object.cptr, "hello-3: thread_2");
/* set start up registers for the new thread */
seL4_UserContext regs = {0};
size_t regs_size = sizeof(seL4_UserContext) / sizeof(seL4_Word);
/* set instruction pointer where the thread shoud start running */
sel4utils_set_instruction_pointer(®s, (seL4_Word)thread_2);
/* check that stack is aligned correctly */
const int stack_alignment_requirement = sizeof(seL4_Word) * 2;
uintptr_t thread_2_stack_top = (uintptr_t)thread_2_stack + sizeof(thread_2_stack);
ZF_LOGF_IF(thread_2_stack_top % (stack_alignment_requirement) != 0,
"Stack top isn't aligned correctly to a %dB boundary.\n"
"\tDouble check to ensure you're not trampling.",
stack_alignment_requirement);
/* set stack pointer for the new thread. remember the stack grows down */
sel4utils_set_stack_pointer(®s, thread_2_stack_top);
/* set the fs register for IPC buffer */
regs.fs = IPCBUF_GDT_SELECTOR;
/* actually write the TCB registers. */
error = seL4_TCB_WriteRegisters(tcb_object.cptr, 0, 0, regs_size, ®s);
ZF_LOGF_IFERR(error, "Failed to write the new thread's register set.\n"
"\tDid you write the correct number of registers? See arg4.\n");
/* start the new thread running */
error = seL4_TCB_Resume(tcb_object.cptr);
ZF_LOGF_IFERR(error, "Failed to start new thread.\n");
/* we are done, say hello */
printf("main: hello world\n");
/*
* now send a message to the new thread, and wait for a reply
*/
seL4_Word msg;
seL4_MessageInfo_t tag;
/* TODO 8: set the data to send. We send it in the first message register */
/* hint 1: seL4_MessageInfo_new()
* seL4_MessageInfo_t CONST seL4_MessageInfo_new(seL4_Uint32 label, seL4_Uint32 capsUnwrapped, seL4_Uint32 extraCaps, seL4_Uint32 length)
* @param label The value of the label field
* @param capsUnwrapped The value of the capsUnwrapped field
* @param extraCaps The value of the extraCaps field
* @param length The number of message registers to send
* @return The seL4_MessageInfo_t containing the given values.
*
* seL4_MessageInfo_new() is generated during build. It can be found in:
* build/x86/pc99/libsel4/include/sel4/types_gen.h
* It is generated from the following definition:
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_8:
*
* hint 2: use 0 for the first 3 fields.
* hint 3: send only 1 message register of data
*
* hint 4: seL4_SetMR()
* void seL4_SetMR(int i, seL4_Word mr)
* @param i The message register to write
* @param mr The value of the message register
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_8:
* You can find out more about message registers in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*
* hint 5: send MSG_DATA
*/
tag = seL4_MessageInfo_new(0, 0, 0, 1);
seL4_SetMR(0, MSG_DATA);
/* TODO 9: send and wait for a reply. */
/* hint: seL4_Call()
* seL4_MessageInfo_t seL4_Call(seL4_CPtr dest, seL4_MessageInfo_t msgInfo)
* @param dest The capability to be invoked.
* @param msgInfo The messageinfo structure for the IPC. This specifies information about the message to send (such as the number of message registers to send).
* @return A seL4_MessageInfo_t structure. This is information about the repy message.
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_9:
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*
* hint 2: seL4_MessageInfo_t is generated during build.
* The type definition and generated field access functions are defined in a generated file:
* build/x86/pc99/libsel4/include/sel4/types_gen.h
* It is generated from the following definition:
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_9:
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*/
tag = seL4_Call(ep_cap_path.capPtr, tag);
/* TODO 10: get the reply message */
/* hint: seL4_GetMR()
* seL4_Word seL4_GetMR(int i)
* @param i The message register to retreive
* @return The message register value
* Link to source: https://wiki.sel4.systems/seL4%20Tutorial%203#TODO_10:
* You can find out more about message registers in the API manual: http://sel4.systems/Info/Docs/seL4-manual-3.0.0.pdf
*/
msg = seL4_GetMR(0);
/* check that we got the expected repy */
ZF_LOGF_IF(seL4_MessageInfo_get_length(tag) != 1,
"Response data from thread_2 was not the length expected.\n"
"\tHow many registers did you set with seL4_SetMR within thread_2?\n");
ZF_LOGF_IF(msg != ~MSG_DATA,
"Response data from thread_2's content was not what was expected.\n");
printf("main: got a reply: %#x\n", msg);
return 0;
}
int main(void)
{
UNUSED int error;
/* give us a name: useful for debugging if the thread faults */
name_thread(seL4_CapInitThreadTCB, "hello-3");
/* get boot info */
info = seL4_GetBootInfo();
/* init simple */
simple_default_init_bootinfo(&simple, info);
/* print out bootinfo and other info about simple */
simple_print(&simple);
/* create an allocator */
allocman = bootstrap_use_current_simple(&simple, ALLOCATOR_STATIC_POOL_SIZE, allocator_mem_pool);
assert(allocman);
/* create a vka (interface for interacting with the underlying allocator) */
allocman_make_vka(&vka, allocman);
/* get our cspace root cnode */
seL4_CPtr cspace_cap;
cspace_cap = simple_get_cnode(&simple);
/* get our vspace root page directory */
seL4_CPtr pd_cap;
pd_cap = simple_get_pd(&simple);
/* create a new TCB */
vka_object_t tcb_object = {0};
error = vka_alloc_tcb(&vka, &tcb_object);
assert(error == 0);
/*
* create and map an ipc buffer:
*/
/* TODO 1: get a frame cap for the ipc buffer */
/* hint: vka_alloc_frame()
* int vka_alloc_frame(vka_t *vka, uint32_t size_bits, vka_object_t *result)
* @param vka Pointer to vka interface.
* @param size_bits Frame size: 2^size_bits
* @param result Structure for the Frame object. This gets initialised.
* @return 0 on success
* https://github.com/seL4/libsel4vka/blob/master/include/vka/object.h#L147
*/
vka_object_t ipc_frame_object;
error = vka_alloc_frame(&vka, IPCBUF_FRAME_SIZE_BITS, &ipc_frame_object);
assert(error == 0);
/*
* map the frame into the vspace at ipc_buffer_vaddr.
* To do this we first try to map it in to the root page directory.
* If there is already a page table mapped in the appropriate slot in the
* page diretory where we can insert this frame, then this will succeed.
* Otherwise we first need to create a page table, and map it in to
* the page directory, before we can map the frame in. */
seL4_Word ipc_buffer_vaddr = IPCBUF_VADDR;
/* TODO 2: try to map the frame the first time */
/* hint 1: seL4_ARCH_Page_Map()
* The *ARCH* versions of seL4 sys calls are abstractions over the architecture provided by libsel4utils
* this one is defined as:
* #define seL4_ARCH_Page_Map seL4_IA32_Page_Map
* in: https://github.com/seL4/libsel4utils/blob/master/include/sel4utils/mapping.h#L69
* The signature for the underlying function is:
* int seL4_IA32_Page_Map(seL4_IA32_Page service, seL4_IA32_PageDirectory pd, seL4_Word vaddr, seL4_CapRights rights, seL4_IA32_VMAttributes attr)
* @param service Capability to the page to map.
* @param pd Capability to the VSpace which will contain the mapping.
* @param vaddr Virtual address to map the page into.
* @param rights Rights for the mapping.
* @param attr VM Attributes for the mapping.
* @return 0 on success.
*
* Note: this function is generated during build. It is generated from the following definition:
* https://github.com/seL4/seL4/blob/master/libsel4/arch_include/x86/interfaces/sel4arch.xml#L52
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*
* hint 2: for the rights, use seL4_AllRights
* hint 3: for VM attributes use seL4_ARCH_Default_VMAttributes
*/
error = seL4_ARCH_Page_Map(ipc_frame_object.cptr, pd_cap, ipc_buffer_vaddr,
seL4_AllRights, seL4_ARCH_Default_VMAttributes);
if (error != 0) {
/* TODO 3: create a page table */
/* hint: vka_alloc_page_table()
* int vka_alloc_page_table(vka_t *vka, vka_object_t *result)
* @param vka Pointer to vka interface.
* @param result Structure for the PageTable object. This gets initialised.
* @return 0 on success
* https://github.com/seL4/libsel4vka/blob/master/include/vka/object.h#L178
*/
vka_object_t pt_object;
error = vka_alloc_page_table(&vka, &pt_object);
assert(error == 0);
/* TODO 4: map the page table */
/* hint 1: seL4_ARCH_PageTable_Map()
* The *ARCH* versions of seL4 sys calls are abstractions over the architecture provided by libsel4utils
* this one is defined as:
* #define seL4_ARCH_PageTable_Map seL4_IA32_PageTable_Map
* in: https://github.com/seL4/libsel4utils/blob/master/include/sel4utils/mapping.h#L73
* The signature for the underlying function is:
* int seL4_IA32_PageTable_Map(seL4_IA32_PageTable service, seL4_IA32_PageDirectory pd, seL4_Word vaddr, seL4_IA32_VMAttributes attr)
* @param service Capability to the page table to map.
* @param pd Capability to the VSpace which will contain the mapping.
* @param vaddr Virtual address to map the page table into.
* @param rights Rights for the mapping.
* @param attr VM Attributes for the mapping.
* @return 0 on success.
*
* Note: this function is generated during build. It is generated from the following definition:
* https://github.com/seL4/seL4/blob/master/libsel4/arch_include/x86/interfaces/sel4arch.xml#L37
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*
* hint 2: for VM attributes use seL4_ARCH_Default_VMAttributes
*/
error = seL4_ARCH_PageTable_Map(pt_object.cptr, pd_cap,
ipc_buffer_vaddr, seL4_ARCH_Default_VMAttributes);
assert(error == 0);
/* TODO 5: then map the frame in */
/* hint 1: use seL4_ARCH_Page_Map() as above
* hint 2: for the rights, use seL4_AllRights
* hint 3: for VM attributes use seL4_ARCH_Default_VMAttributes
*/
error = seL4_ARCH_Page_Map(ipc_frame_object.cptr, pd_cap,
ipc_buffer_vaddr, seL4_AllRights, seL4_ARCH_Default_VMAttributes);
assert(error == 0);
}
/* set the IPC buffer's virtual address in a field of the IPC buffer */
seL4_IPCBuffer *ipcbuf = (seL4_IPCBuffer*)ipc_buffer_vaddr;
ipcbuf->userData = ipc_buffer_vaddr;
/* TODO 6: create an endpoint */
/* hint: vka_alloc_endpoint()
* int vka_alloc_endpoint(vka_t *vka, vka_object_t *result)
* @param vka Pointer to vka interface.
* @param result Structure for the Endpoint object. This gets initialised.
* @return 0 on success
* https://github.com/seL4/libsel4vka/blob/master/include/vka/object.h#L94
*/
error = vka_alloc_endpoint(&vka, &ep_object);
assert(error == 0);
/* TODO 7: make a badged copy of it in our cspace. This copy will be used to send
* an IPC message to the original cap */
/* hint 1: vka_mint_object()
* int vka_mint_object(vka_t *vka, vka_object_t *object, cspacepath_t *result, seL4_CapRights rights, seL4_CapData_t badge)
* @param[in] vka The allocator for the cspace.
* @param[in] object Target object for cap minting.
* @param[out] result Allocated cspacepath.
* @param[in] rights The rights for the minted cap.
* @param[in] badge The badge for the minted cap.
* @return 0 on success
*
* https://github.com/seL4/libsel4vka/blob/master/include/vka/object_capops.h#L41
*
* hint 2: for the rights, use seL4_AllRights
* hint 3: for the badge use seL4_CapData_Badge_new()
* seL4_CapData_t CONST seL4_CapData_Badge_new(seL4_Uint32 Badge)
* @param[in] Badge The badge number to use
* @return A CapData structure containing the desired badge info
*
* seL4_CapData_t is generated during build.
* The type definition and generated field access functions are defined in a generated file:
* build/x86/pc99/libsel4/include/sel4/types_gen.h
* It is generated from the following definition:
* https://github.com/seL4/seL4/blob/master/libsel4/include/sel4/types.bf#L30
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*
* hint 4: for the badge use EP_BADGE
*/
error = vka_mint_object(&vka, &ep_object, &ep_cap_path, seL4_AllRights,
seL4_CapData_Badge_new(EP_BADGE));
assert(error == 0);
/* initialise the new TCB */
error = seL4_TCB_Configure(tcb_object.cptr, seL4_CapNull, seL4_MaxPrio,
cspace_cap, seL4_NilData, pd_cap, seL4_NilData,
ipc_buffer_vaddr, ipc_frame_object.cptr);
assert(error == 0);
/* give the new thread a name */
name_thread(tcb_object.cptr, "hello-3: thread_2");
/* set start up registers for the new thread */
seL4_UserContext regs = {0};
size_t regs_size = sizeof(seL4_UserContext) / sizeof(seL4_Word);
/* set instruction pointer where the thread shoud start running */
sel4utils_set_instruction_pointer(®s, (seL4_Word)thread_2);
/* check that stack is aligned correctly */
uintptr_t thread_2_stack_top = (uintptr_t)thread_2_stack + sizeof(thread_2_stack);
assert(thread_2_stack_top % (sizeof(seL4_Word) * 2) == 0);
/* set stack pointer for the new thread. remember the stack grows down */
sel4utils_set_stack_pointer(®s, thread_2_stack_top);
/* set the gs register for thread local storage */
regs.gs = IPCBUF_GDT_SELECTOR;
/* actually write the TCB registers. */
error = seL4_TCB_WriteRegisters(tcb_object.cptr, 0, 0, regs_size, ®s);
assert(error == 0);
/* start the new thread running */
error = seL4_TCB_Resume(tcb_object.cptr);
assert(error == 0);
/* we are done, say hello */
printf("main: hello world\n");
/*
* now send a message to the new thread, and wait for a reply
*/
seL4_Word msg;
seL4_MessageInfo_t tag;
/* TODO 8: set the data to send. We send it in the first message register */
/* hint 1: seL4_MessageInfo_new()
* seL4_MessageInfo_t CONST seL4_MessageInfo_new(seL4_Uint32 label, seL4_Uint32 capsUnwrapped, seL4_Uint32 extraCaps, seL4_Uint32 length)
* @param label The value of the label field
* @param capsUnwrapped The value of the capsUnwrapped field
* @param extraCaps The value of the extraCaps field
* @param length The number of message registers to send
* @return The seL4_MessageInfo_t containing the given values.
*
* seL4_MessageInfo_new() is generated during build. It can be found in:
* build/x86/pc99/libsel4/include/sel4/types_gen.h
* It is generated from the following definition:
* https://github.com/seL4/seL4/blob/master/libsel4/include/sel4/types.bf#L35
*
* hint 2: use 0 for the first 3 fields.
* hint 3: send only 1 message register of data
*
* hint 4: seL4_SetMR()
* void seL4_SetMR(int i, seL4_Word mr)
* @param i The message register to write
* @param mr The value of the message register
* https://github.com/seL4/seL4/blob/master/libsel4/arch_include/x86/sel4/arch/functions.h#L41
* You can find out more about message registers in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*
* hint 5: send MSG_DATA
*/
tag = seL4_MessageInfo_new(0, 0, 0, 1);
seL4_SetMR(0, MSG_DATA);
/* TODO 9: send and wait for a reply. */
/* hint: seL4_Call()
* seL4_MessageInfo_t seL4_Call(seL4_CPtr dest, seL4_MessageInfo_t msgInfo)
* @param dest The capability to be invoked.
* @param msgInfo The messageinfo structure for the IPC. This specifies information about the message to send (such as the number of message registers to send).
* @return A seL4_MessageInfo_t structure. This is information about the repy message.
* https://github.com/seL4/seL4/blob/master/libsel4/arch_include/x86/sel4/arch/syscalls.h#L242
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*
* hint 2: seL4_MessageInfo_t is generated during build.
* The type definition and generated field access functions are defined in a generated file:
* build/x86/pc99/libsel4/include/sel4/types_gen.h
* It is generated from the following definition:
* https://github.com/seL4/seL4/blob/master/libsel4/include/sel4/types.bf#L35
* You can find out more about it in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*/
tag = seL4_Call(ep_cap_path.capPtr, tag);
/* TODO 10: get the reply message */
/* hint: seL4_GetMR()
* seL4_Word seL4_GetMR(int i)
* @param i The message register to retreive
* @return The message register value
* https://github.com/seL4/seL4/blob/master/libsel4/arch_include/x86/sel4/arch/functions.h#L33
* You can find out more about message registers in the API manual: http://sel4.systems/Info/Docs/seL4-manual.pdf
*/
msg = seL4_GetMR(0);
/* check that we got the expected repy */
assert(seL4_MessageInfo_get_length(tag) == 1);
assert(msg == ~MSG_DATA);
printf("main: got a reply: %#x\n", msg);
return 0;
}
int main(void)
{
UNUSED int error;
/* give us a name: useful for debugging if the thread faults */
name_thread(seL4_CapInitThreadTCB, "hello-2");
/* get boot info */
info = seL4_GetBootInfo();
/* init simple */
simple_default_init_bootinfo(&simple, info);
/* print out bootinfo and other info about simple */
simple_print(&simple);
/* create an allocator */
allocman = bootstrap_use_current_simple(&simple, ALLOCATOR_STATIC_POOL_SIZE,
allocator_mem_pool);
assert(allocman);
/* create a vka (interface for interacting with the underlying allocator) */
allocman_make_vka(&vka, allocman);
/* get our cspace root cnode */
seL4_CPtr cspace_cap;
cspace_cap = simple_get_cnode(&simple);
/* get our vspace root page diretory */
seL4_CPtr pd_cap;
pd_cap = simple_get_pd(&simple);
/* create a new TCB */
vka_object_t tcb_object = {0};
error = vka_alloc_tcb(&vka, &tcb_object);
assert(error == 0);
/* initialise the new TCB */
error = seL4_TCB_Configure(tcb_object.cptr, seL4_CapNull, seL4_MaxPrio,
cspace_cap, seL4_NilData, pd_cap, seL4_NilData, 0, 0);
assert(error == 0);
/* give the new thread a name */
name_thread(tcb_object.cptr, "hello-2: thread_2");
/* set start up registers for the new thread: */
seL4_UserContext regs = {0};
/* set instruction pointer where the thread shoud start running */
sel4utils_set_instruction_pointer(®s, (seL4_Word)thread_2);
/* check that stack is aligned correctly */
uintptr_t thread_2_stack_top = (uintptr_t)thread_2_stack + sizeof(thread_2_stack);
assert(thread_2_stack_top % (sizeof(seL4_Word) * 2) == 0);
/* set stack pointer for the new thread. remember the stack grows down */
sel4utils_set_stack_pointer(®s, thread_2_stack_top);
/* actually write the TCB registers. we write 2 registers:
* instruction pointer is first, stack pointer is second. */
error = seL4_TCB_WriteRegisters(tcb_object.cptr, 0, 0, 2, ®s);
assert(error == 0);
/* start the new thread running */
error = seL4_TCB_Resume(tcb_object.cptr);
assert(error == 0);
/* we are done, say hello */
printf("main: hello world\n");
return 0;
}
static int
vmm_init(void)
{
vka_object_t fault_ep_obj;
vka_t* vka;
simple_t* simple;
vspace_t* vspace;
int err;
vka = &_vka;
vspace = &_vspace;
simple = &_simple;
fault_ep_obj.cptr = 0;
/* Camkes adds nothing to our address space, so this array is empty */
void *existing_frames[] = {
NULL
};
camkes_make_simple(simple);
start_extra_frame_caps = simple_last_valid_cap(simple) + 1;
/* Initialize allocator */
allocman = bootstrap_use_current_1level(
simple_get_cnode(simple),
simple_get_cnode_size_bits(simple),
simple_last_valid_cap(simple) + 1 + num_extra_frame_caps,
BIT(simple_get_cnode_size_bits(simple)),
sizeof(allocator_mempool), allocator_mempool
);
assert(allocman);
err = allocman_add_simple_untypeds(allocman, simple);
assert(!err);
allocman_make_vka(vka, allocman);
/* Initialize the vspace */
err = sel4utils_bootstrap_vspace(vspace, &_alloc_data,
simple_get_init_cap(simple, seL4_CapInitThreadPD), vka, NULL, NULL, existing_frames);
assert(!err);
/* Initialise device support */
err = sel4platsupport_new_io_mapper(*simple, *vspace, *vka,
&_io_ops.io_mapper);
assert(!err);
/* Initialise MUX subsystem */
err = mux_sys_init(&_io_ops, &_io_ops.mux_sys);
assert(!err);
/* Initialise DMA */
err = dma_dmaman_init(&_dma_morecore, NULL, &_io_ops.dma_manager);
assert(!err);
/* Allocate an endpoint for listening to events */
err = vka_alloc_endpoint(vka, &fault_ep_obj);
assert(!err);
_fault_endpoint = fault_ep_obj.cptr;
/* Create an IRQ server */
err = irq_server_new(vspace, vka, simple_get_cnode(simple), IRQSERVER_PRIO,
simple, fault_ep_obj.cptr,
IRQ_MESSAGE_LABEL, 256, &_irq_server);
assert(!err);
return 0;
}
