osblog/risc_v/ch6/src/page.rs

// page.rs
// Memory routines
// Stephen Marz
// 6 October 2019

use core::{mem::size_of, ptr::null_mut};

// ////////////////////////////////
// // Allocation routines
// ////////////////////////////////
extern "C" {
	static HEAP_START: usize;
	static HEAP_SIZE: usize;
}

// We will use ALLOC_START to mark the start of the actual
// memory we can dish out.
static mut ALLOC_START: usize = 0;
const PAGE_ORDER: usize = 12;
pub const PAGE_SIZE: usize = 1 << 12;

/// Align (set to a multiple of some power of two)
/// This takes an order which is the exponent to 2^order
/// Therefore, all alignments must be made as a power of two.
/// This function always rounds up.
pub const fn align_val(val: usize, order: usize) -> usize {
	let o = (1usize << order) - 1;
	(val + o) & !o
}

#[repr(u8)]
pub enum PageBits {
	Empty = 0,
	Taken = 1 << 0,
	Last = 1 << 1,
}

impl PageBits {
	// We convert PageBits to a u8 a lot, so this is
	// for convenience.
	pub fn val(self) -> u8 {
		self as u8
	}
}

// Each page is described by the Page structure. Linux does this
// as well, where each 4096-byte chunk of memory has a structure
// associated with it. However, there structure is much larger.
pub struct Page {
	flags: u8,
}

impl Page {
	// If this page has been marked as the final allocation,
	// this function returns true. Otherwise, it returns false.
	pub fn is_last(&self) -> bool {
		if self.flags & PageBits::Last.val() != 0 {
			true
		}
		else {
			false
		}
	}

	// If the page is marked as being taken (allocated), then
	// this function returns true. Otherwise, it returns false.
	pub fn is_taken(&self) -> bool {
		if self.flags & PageBits::Taken.val() != 0 {
			true
		}
		else {
			false
		}
	}

	// This is the opposite of is_taken().
	pub fn is_free(&self) -> bool {
		!self.is_taken()
	}

	// Clear the Page structure and all associated allocations.
	pub fn clear(&mut self) {
		self.flags = PageBits::Empty.val();
	}

	// Set a certain flag. We ran into trouble here since PageBits
	// is an enumeration and we haven't implemented the BitOr Trait
	// on it.
	pub fn set_flag(&mut self, flag: PageBits) {
		self.flags |= flag.val();
	}

	pub fn clear_flag(&mut self, flag: PageBits) {
		self.flags &= !(flag.val());
	}
}

/// Initialize the allocation system. There are several ways that we can
/// implement the page allocator:
/// 1. Free list (singly linked list where it starts at the first free
/// allocation) 2. Bookkeeping list (structure contains a taken and length)
/// 3. Allocate one Page structure per 4096 bytes (this is what I chose)
/// 4. Others
pub fn init() {
	unsafe {
		// let desc_per_page = PAGE_SIZE / size_of::<Page>();
		let num_pages = HEAP_SIZE / PAGE_SIZE;
		// let num_desc_pages = num_pages / desc_per_page;
		let ptr = HEAP_START as *mut Page;
		// Clear all pages to make sure that they aren't accidentally
		// taken
		for i in 0..num_pages {
			(*ptr.add(i)).clear();
		}
		// Determine where the actual useful memory starts. This will be
		// after all Page structures. We also must align the ALLOC_START
		// to a page-boundary (PAGE_SIZE = 4096). ALLOC_START =
		// (HEAP_START + num_pages * size_of::<Page>() + PAGE_SIZE - 1)
		// & !(PAGE_SIZE - 1);
		ALLOC_START = align_val(
		                        HEAP_START
		                        + num_pages * size_of::<Page>(),
		                        PAGE_ORDER,
		);
	}
}

/// Allocate a page or multiple pages
/// pages: the number of PAGE_SIZE pages to allocate
pub fn alloc(pages: usize) -> *mut u8 {
	// We have to find a contiguous allocation of pages
	assert!(pages > 0);
	unsafe {
		// We create a Page structure for each page on the heap. We
		// actually might have more since HEAP_SIZE moves and so does
		// the size of our structure, but we'll only waste a few bytes.
		let num_pages = HEAP_SIZE / PAGE_SIZE;
		let ptr = HEAP_START as *mut Page;
		for i in 0..num_pages - pages {
			let mut found = false;
			// Check to see if this Page is free. If so, we have our
			// first candidate memory address.
			if (*ptr.add(i)).is_free() {
				// It was FREE! Yay!
				found = true;
				for j in i..i + pages {
					// Now check to see if we have a
					// contiguous allocation for all of the
					// request pages. If not, we should
					// check somewhere else.
					if (*ptr.add(j)).is_taken() {
						found = false;
						break;
					}
				}
			}
			// We've checked to see if there are enough contiguous
			// pages to form what we need. If we couldn't, found
			// will be false, otherwise it will be true, which means
			// we've found valid memory we can allocate.
			if found {
				for k in i..i + pages - 1 {
					(*ptr.add(k)).set_flag(PageBits::Taken);
				}
				// The marker for the last page is
				// PageBits::Last This lets us know when we've
				// hit the end of this particular allocation.
				(*ptr.add(i+pages-1)).set_flag(PageBits::Taken);
				(*ptr.add(i+pages-1)).set_flag(PageBits::Last);
				// The Page structures themselves aren't the
				// useful memory. Instead, there is 1 Page
				// structure per 4096 bytes starting at
				// ALLOC_START.
				return (ALLOC_START + PAGE_SIZE * i)
				       as *mut u8;
			}
		}
	}

	// If we get here, that means that no contiguous allocation was
	// found.
	null_mut()
}

/// Allocate and zero a page or multiple pages
/// pages: the number of pages to allocate
/// Each page is PAGE_SIZE which is calculated as 1 << PAGE_ORDER
/// On RISC-V, this typically will be 4,096 bytes.
pub fn zalloc(pages: usize) -> *mut u8 {
	// Allocate and zero a page.
	// First, let's get the allocation
	let ret = alloc(pages);
	if !ret.is_null() {
		let size = (PAGE_SIZE * pages) / 8;
		let big_ptr = ret as *mut u64;
		for i in 0..size {
			// We use big_ptr so that we can force an
			// sd (store doubleword) instruction rather than
			// the sb. This means 8x fewer stores than before.
			// Typically we have to be concerned about remaining
			// bytes, but fortunately 4096 % 8 = 0, so we
			// won't have any remaining bytes.
			unsafe {
				(*big_ptr.add(i)) = 0;
			}
		}
	}
	ret
}

/// Deallocate a page by its pointer
/// The way we've structured this, it will automatically coalesce
/// contiguous pages.
pub fn dealloc(ptr: *mut u8) {
	// Make sure we don't try to free a null pointer.
	assert!(!ptr.is_null());
	unsafe {
		let addr =
			HEAP_START + (ptr as usize - ALLOC_START) / PAGE_SIZE;
		// Make sure that the address makes sense. The address we
		// calculate here is the page structure, not the HEAP address!
		assert!(addr >= HEAP_START && addr < HEAP_START + HEAP_SIZE);
		let mut p = addr as *mut Page;
		// Keep clearing pages until we hit the last page.
		while (*p).is_taken() && !(*p).is_last() {
			(*p).clear();
			p = p.add(1);
		}
		// If the following assertion fails, it is most likely
		// caused by a double-free.
		assert!(
		        (*p).is_last() == true,
		        "Possible double-free detected! (Not taken found \
		         before last)"
		);
		// If we get here, we've taken care of all previous pages and
		// we are on the last page.
		(*p).clear();
	}
}

/// Print all page allocations
/// This is mainly used for debugging.
pub fn print_page_allocations() {
	unsafe {
		let num_pages = (HEAP_SIZE - (ALLOC_START - HEAP_START)) / PAGE_SIZE;
		let mut beg = HEAP_START as *const Page;
		let end = beg.add(num_pages);
		let alloc_beg = ALLOC_START;
		let alloc_end = ALLOC_START + num_pages * PAGE_SIZE;
		println!();
		println!(
		         "PAGE ALLOCATION TABLE\nMETA: {:p} -> {:p}\nPHYS: \
		          0x{:x} -> 0x{:x}",
		         beg, end, alloc_beg, alloc_end
		);
		println!("~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~");
		let mut num = 0;
		while beg < end {
			if (*beg).is_taken() {
				let start = beg as usize;
				let memaddr = ALLOC_START
				              + (start - HEAP_START)
				                * PAGE_SIZE;
				print!("0x{:x} => ", memaddr);
				loop {
					num += 1;
					if (*beg).is_last() {
						let end = beg as usize;
						let memaddr = ALLOC_START
						              + (end
						                 - HEAP_START)
						                * PAGE_SIZE
						              + PAGE_SIZE - 1;
						print!(
						       "0x{:x}: {:>3} page(s)",
						       memaddr,
						       (end - start + 1)
						);
						println!(".");
						break;
					}
					beg = beg.add(1);
				}
			}
			beg = beg.add(1);
		}
		println!("~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~");
		println!(
		         "Allocated: {:>6} pages ({:>10} bytes).",
		         num,
		         num * PAGE_SIZE
		);
		println!(
		         "Free     : {:>6} pages ({:>10} bytes).",
		         num_pages - num,
		         (num_pages - num) * PAGE_SIZE
		);
		println!();
	}
}

// ////////////////////////////////
// // MMU Routines
// ////////////////////////////////

// Represent (repr) our entry bits as
// unsigned 64-bit integers.
#[repr(i64)]
#[derive(Copy, Clone)]
pub enum EntryBits {
	None = 0,
	Valid = 1 << 0,
	Read = 1 << 1,
	Write = 1 << 2,
	Execute = 1 << 3,
	User = 1 << 4,
	Global = 1 << 5,
	Access = 1 << 6,
	Dirty = 1 << 7,

	// Convenience combinations
	ReadWrite = 1 << 1 | 1 << 2,
	ReadExecute = 1 << 1 | 1 << 3,
	ReadWriteExecute = 1 << 1 | 1 << 2 | 1 << 3,

	// User Convenience Combinations
	UserReadWrite = 1 << 1 | 1 << 2 | 1 << 4,
	UserReadExecute = 1 << 1 | 1 << 3 | 1 << 4,
	UserReadWriteExecute = 1 << 1 | 1 << 2 | 1 << 3 | 1 << 4,
}

// Helper functions to convert the enumeration
// into an i64, which is what our page table
// entries will be.
impl EntryBits {
	pub fn val(self) -> i64 {
		self as i64
	}
}

// A single entry. We're using an i64 so that
// this will sign-extend rather than zero-extend
// since RISC-V requires that the reserved sections
// take on the most significant bit.
pub struct Entry {
	pub entry: i64,
}

// The Entry structure describes one of the 512 entries per table, which is
// described in the RISC-V privileged spec Figure 4.18.
impl Entry {
	pub fn is_valid(&self) -> bool {
		self.get_entry() & EntryBits::Valid.val() != 0
	}

	// The first bit (bit index #0) is the V bit for
	// valid.
	pub fn is_invalid(&self) -> bool {
		!self.is_valid()
	}

	// A leaf has one or more RWX bits set
	pub fn is_leaf(&self) -> bool {
		self.get_entry() & 0xe != 0
	}

	pub fn is_branch(&self) -> bool {
		!self.is_leaf()
	}

	pub fn set_entry(&mut self, entry: i64) {
		self.entry = entry;
	}

	pub fn get_entry(&self) -> i64 {
		self.entry
	}
}

// Table represents a single table, which contains 512 (2^9), 64-bit entries.
pub struct Table {
	pub entries: [Entry; 512],
}

impl Table {
	pub fn len() -> usize {
		512
	}
}

/// Map a virtual address to a physical address using 4096-byte page
/// size.
/// root: a mutable reference to the root Table
/// vaddr: The virtual address to map
/// paddr: The physical address to map
/// bits: An OR'd bitset containing the bits the leaf should have.
///       The bits should contain only the following:
///          Read, Write, Execute, User, and/or Global
///       The bits MUST include one or more of the following:
///          Read, Write, Execute
///       The valid bit automatically gets added.
pub fn map(root: &mut Table,
           vaddr: usize,
           paddr: usize,
           bits: i64,
           level: usize)
{
	// Make sure that Read, Write, or Execute have been provided
	// otherwise, we'll leak memory and always create a page fault.
	assert!(bits & 0xe != 0);
	// Extract out each VPN from the virtual address
	// On the virtual address, each VPN is exactly 9 bits,
	// which is why we use the mask 0x1ff = 0b1_1111_1111 (9 bits)
	let vpn = [
	           // VPN[0] = vaddr[20:12]
	           (vaddr >> 12) & 0x1ff,
	           // VPN[1] = vaddr[29:21]
	           (vaddr >> 21) & 0x1ff,
	           // VPN[2] = vaddr[38:30]
	           (vaddr >> 30) & 0x1ff,
	];

	// Just like the virtual address, extract the physical address
	// numbers (PPN). However, PPN[2] is different in that it stores
	// 26 bits instead of 9. Therefore, we use,
	// 0x3ff_ffff = 0b11_1111_1111_1111_1111_1111_1111 (26 bits).
	let ppn = [
	           // PPN[0] = paddr[20:12]
	           (paddr >> 12) & 0x1ff,
	           // PPN[1] = paddr[29:21]
	           (paddr >> 21) & 0x1ff,
	           // PPN[2] = paddr[55:30]
	           (paddr >> 30) & 0x3ff_ffff,
	];
	// We will use this as a floating reference so that we can set
	// individual entries as we walk the table.
	let mut v = &mut root.entries[vpn[2]];
	// Now, we're going to traverse the page table and set the bits
	// properly. We expect the root to be valid, however we're required to
	// create anything beyond the root.
	// In Rust, we create a range iterator using the .. operator.
	// The .rev() will reverse the iteration since we need to start with
	// VPN[2] The .. operator is inclusive on start but exclusive on end.
	// So, (0..2) will iterate 0 and 1.
	for i in (level..2).rev() {
		if !v.is_valid() {
			// Allocate a page
			let page = zalloc(1);
			// The page is already aligned by 4,096, so store it
			// directly The page is stored in the entry shifted
			// right by 2 places.
			v.set_entry(
			            (page as i64 >> 2)
			            | EntryBits::Valid.val(),
			);
		}
		let entry = ((v.get_entry() & !0x3ff) << 2) as *mut Entry;
		v = unsafe { entry.add(vpn[i]).as_mut().unwrap() };
	}
	// When we get here, we should be at VPN[0] and v should be pointing to
	// our entry.
	// The entry structure is Figure 4.18 in the RISC-V Privileged
	// Specification
	let entry = (ppn[2] << 28) as i64 |   // PPN[2] = [53:28]
	            (ppn[1] << 19) as i64 |   // PPN[1] = [27:19]
				(ppn[0] << 10) as i64 |   // PPN[0] = [18:10]
				bits |                    // Specified bits, such as User, Read, Write, etc
				EntryBits::Valid.val() |  // Valid bit
				EntryBits::Dirty.val() |  // Some machines require this to =1
				EntryBits::Access.val()   // Just like dirty, some machines require this
				;
	// Set the entry. V should be set to the correct pointer by the loop
	// above.
	v.set_entry(entry);
}

/// Unmaps and frees all memory associated with a table.
/// root: The root table to start freeing.
/// NOTE: This does NOT free root directly. This must be
/// freed manually.
/// The reason we don't free the root is because it is
/// usually embedded into the Process structure.
pub fn unmap(root: &mut Table) {
	// Start with level 2
	for lv2 in 0..Table::len() {
		let ref entry_lv2 = root.entries[lv2];
		if entry_lv2.is_valid() && entry_lv2.is_branch() {
			// This is a valid entry, so drill down and free.
			let memaddr_lv1 = (entry_lv2.get_entry() & !0x3ff) << 2;
			let table_lv1 = unsafe {
				// Make table_lv1 a mutable reference instead of
				// a pointer.
				(memaddr_lv1 as *mut Table).as_mut().unwrap()
			};
			for lv1 in 0..Table::len() {
				let ref entry_lv1 = table_lv1.entries[lv1];
				if entry_lv1.is_valid() && entry_lv1.is_branch()
				{
					let memaddr_lv0 = (entry_lv1.get_entry()
					                   & !0x3ff) << 2;
					// The next level is level 0, which
					// cannot have branches, therefore,
					// we free here.
					dealloc(memaddr_lv0 as *mut u8);
				}
			}
			dealloc(memaddr_lv1 as *mut u8);
		}
	}
}

/// Walk the page table to convert a virtual address to a
/// physical address.
/// If a page fault would occur, this returns None
/// Otherwise, it returns Some with the physical address.
pub fn virt_to_phys(root: &Table, vaddr: usize) -> Option<usize> {
	// Walk the page table pointed to by root
	let vpn = [
	           // VPN[0] = vaddr[20:12]
	           (vaddr >> 12) & 0x1ff,
	           // VPN[1] = vaddr[29:21]
	           (vaddr >> 21) & 0x1ff,
	           // VPN[2] = vaddr[38:30]
	           (vaddr >> 30) & 0x1ff,
	];

	let mut v = &root.entries[vpn[2]];
	for i in (0..=2).rev() {
		if v.is_invalid() {
			// This is an invalid entry, page fault.
			break;
		}
		else if v.is_leaf() {
			// According to RISC-V, a leaf can be at any level.

			// The offset mask masks off the PPN. Each PPN is 9
			// bits and they start at bit #12. So, our formula
			// 12 + i * 9
			let off_mask = (1 << (12 + i * 9)) - 1;
			let vaddr_pgoff = vaddr & off_mask;
			let addr = ((v.get_entry() << 2) as usize) & !off_mask;
			return Some(addr | vaddr_pgoff);
		}
		// Set v to the next entry which is pointed to by this
		// entry. However, the address was shifted right by 2 places
		// when stored in the page table entry, so we shift it left
		// to get it back into place.
		let entry = ((v.get_entry() & !0x3ff) << 2) as *const Entry;
		// We do i - 1 here, however we should get None or Some() above
		// before we do 0 - 1 = -1.
		v = unsafe { entry.add(vpn[i - 1]).as_ref().unwrap() };
	}

	// If we get here, we've exhausted all valid tables and haven't
	// found a leaf.
	None
}
Added chapter 6 2019-11-27 21:59:29 +04:00			`// page.rs`
			`// Memory routines`
			`// Stephen Marz`
			`// 6 October 2019`

			`use core::{mem::size_of, ptr::null_mut};`

			`// ////////////////////////////////`
			`// // Allocation routines`
			`// ////////////////////////////////`
			`extern "C" {`
			`static HEAP_START: usize;`
			`static HEAP_SIZE: usize;`
			`}`

			`// We will use ALLOC_START to mark the start of the actual`
			`// memory we can dish out.`
			`static mut ALLOC_START: usize = 0;`
			`const PAGE_ORDER: usize = 12;`
			`pub const PAGE_SIZE: usize = 1 << 12;`

			`/// Align (set to a multiple of some power of two)`
			`/// This takes an order which is the exponent to 2^order`
			`/// Therefore, all alignments must be made as a power of two.`
			`/// This function always rounds up.`
			`pub const fn align_val(val: usize, order: usize) -> usize {`
			`let o = (1usize << order) - 1;`
			`(val + o) & !o`
			`}`

			`#[repr(u8)]`
			`pub enum PageBits {`
			`Empty = 0,`
			`Taken = 1 << 0,`
			`Last = 1 << 1,`
			`}`

			`impl PageBits {`
			`// We convert PageBits to a u8 a lot, so this is`
			`// for convenience.`
			`pub fn val(self) -> u8 {`
			`self as u8`
			`}`
			`}`

			`// Each page is described by the Page structure. Linux does this`
			`// as well, where each 4096-byte chunk of memory has a structure`
			`// associated with it. However, there structure is much larger.`
			`pub struct Page {`
			`flags: u8,`
			`}`

			`impl Page {`
			`// If this page has been marked as the final allocation,`
			`// this function returns true. Otherwise, it returns false.`
			`pub fn is_last(&self) -> bool {`
			`if self.flags & PageBits::Last.val() != 0 {`
			`true`
			`}`
			`else {`
			`false`
			`}`
			`}`

			`// If the page is marked as being taken (allocated), then`
			`// this function returns true. Otherwise, it returns false.`
			`pub fn is_taken(&self) -> bool {`
			`if self.flags & PageBits::Taken.val() != 0 {`
			`true`
			`}`
			`else {`
			`false`
			`}`
			`}`

			`// This is the opposite of is_taken().`
			`pub fn is_free(&self) -> bool {`
			`!self.is_taken()`
			`}`

			`// Clear the Page structure and all associated allocations.`
			`pub fn clear(&mut self) {`
			`self.flags = PageBits::Empty.val();`
			`}`

			`// Set a certain flag. We ran into trouble here since PageBits`
			`// is an enumeration and we haven't implemented the BitOr Trait`
			`// on it.`
			`pub fn set_flag(&mut self, flag: PageBits) {`
			`self.flags \|= flag.val();`
			`}`

			`pub fn clear_flag(&mut self, flag: PageBits) {`
			`self.flags &= !(flag.val());`
			`}`
			`}`

			`/// Initialize the allocation system. There are several ways that we can`
			`/// implement the page allocator:`
			`/// 1. Free list (singly linked list where it starts at the first free`
			`/// allocation) 2. Bookkeeping list (structure contains a taken and length)`
			`/// 3. Allocate one Page structure per 4096 bytes (this is what I chose)`
			`/// 4. Others`
			`pub fn init() {`
			`unsafe {`
			`// let desc_per_page = PAGE_SIZE / size_of::<Page>();`
			`let num_pages = HEAP_SIZE / PAGE_SIZE;`
			`// let num_desc_pages = num_pages / desc_per_page;`
			`let ptr = HEAP_START as *mut Page;`
			`// Clear all pages to make sure that they aren't accidentally`
			`// taken`
			`for i in 0..num_pages {`
			`(*ptr.add(i)).clear();`
			`}`
			`// Determine where the actual useful memory starts. This will be`
			`// after all Page structures. We also must align the ALLOC_START`
			`// to a page-boundary (PAGE_SIZE = 4096). ALLOC_START =`
			`// (HEAP_START + num_pages * size_of::<Page>() + PAGE_SIZE - 1)`
			`// & !(PAGE_SIZE - 1);`
			`ALLOC_START = align_val(`
			`HEAP_START`
			`+ num_pages * size_of::<Page>(),`
			`PAGE_ORDER,`
			`);`
			`}`
			`}`

			`/// Allocate a page or multiple pages`
			`/// pages: the number of PAGE_SIZE pages to allocate`
			`pub fn alloc(pages: usize) -> *mut u8 {`
			`// We have to find a contiguous allocation of pages`
			`assert!(pages > 0);`
			`unsafe {`
			`// We create a Page structure for each page on the heap. We`
			`// actually might have more since HEAP_SIZE moves and so does`
			`// the size of our structure, but we'll only waste a few bytes.`
			`let num_pages = HEAP_SIZE / PAGE_SIZE;`
			`let ptr = HEAP_START as *mut Page;`
			`for i in 0..num_pages - pages {`
			`let mut found = false;`
			`// Check to see if this Page is free. If so, we have our`
			`// first candidate memory address.`
			`if (*ptr.add(i)).is_free() {`
			`// It was FREE! Yay!`
			`found = true;`
			`for j in i..i + pages {`
			`// Now check to see if we have a`
			`// contiguous allocation for all of the`
			`// request pages. If not, we should`
			`// check somewhere else.`
			`if (*ptr.add(j)).is_taken() {`
			`found = false;`
			`break;`
			`}`
			`}`
			`}`
			`// We've checked to see if there are enough contiguous`
			`// pages to form what we need. If we couldn't, found`
			`// will be false, otherwise it will be true, which means`
			`// we've found valid memory we can allocate.`
			`if found {`
			`for k in i..i + pages - 1 {`
			`(*ptr.add(k)).set_flag(PageBits::Taken);`
			`}`
			`// The marker for the last page is`
			`// PageBits::Last This lets us know when we've`
			`// hit the end of this particular allocation.`
			`(*ptr.add(i+pages-1)).set_flag(PageBits::Taken);`
			`(*ptr.add(i+pages-1)).set_flag(PageBits::Last);`
			`// The Page structures themselves aren't the`
			`// useful memory. Instead, there is 1 Page`
			`// structure per 4096 bytes starting at`
			`// ALLOC_START.`
			`return (ALLOC_START + PAGE_SIZE * i)`
			`as *mut u8;`
			`}`
			`}`
			`}`

			`// If we get here, that means that no contiguous allocation was`
			`// found.`
			`null_mut()`
			`}`

			`/// Allocate and zero a page or multiple pages`
			`/// pages: the number of pages to allocate`
			`/// Each page is PAGE_SIZE which is calculated as 1 << PAGE_ORDER`
			`/// On RISC-V, this typically will be 4,096 bytes.`
			`pub fn zalloc(pages: usize) -> *mut u8 {`
			`// Allocate and zero a page.`
			`// First, let's get the allocation`
			`let ret = alloc(pages);`
			`if !ret.is_null() {`
			`let size = (PAGE_SIZE * pages) / 8;`
			`let big_ptr = ret as *mut u64;`
			`for i in 0..size {`
			`// We use big_ptr so that we can force an`
			`// sd (store doubleword) instruction rather than`
			`// the sb. This means 8x fewer stores than before.`
			`// Typically we have to be concerned about remaining`
			`// bytes, but fortunately 4096 % 8 = 0, so we`
			`// won't have any remaining bytes.`
			`unsafe {`
			`(*big_ptr.add(i)) = 0;`
			`}`
			`}`
			`}`
			`ret`
			`}`

			`/// Deallocate a page by its pointer`
			`/// The way we've structured this, it will automatically coalesce`
			`/// contiguous pages.`
			`pub fn dealloc(ptr: *mut u8) {`
			`// Make sure we don't try to free a null pointer.`
			`assert!(!ptr.is_null());`
			`unsafe {`
			`let addr =`
			`HEAP_START + (ptr as usize - ALLOC_START) / PAGE_SIZE;`
			`// Make sure that the address makes sense. The address we`
			`// calculate here is the page structure, not the HEAP address!`
			`assert!(addr >= HEAP_START && addr < HEAP_START + HEAP_SIZE);`
			`let mut p = addr as *mut Page;`
			`// Keep clearing pages until we hit the last page.`
			`while (p).is_taken() && !(p).is_last() {`
			`(*p).clear();`
			`p = p.add(1);`
			`}`
			`// If the following assertion fails, it is most likely`
			`// caused by a double-free.`
			`assert!(`
			`(*p).is_last() == true,`
			`"Possible double-free detected! (Not taken found \`
			`before last)"`
			`);`
			`// If we get here, we've taken care of all previous pages and`
			`// we are on the last page.`
			`(*p).clear();`
			`}`
			`}`

			`/// Print all page allocations`
			`/// This is mainly used for debugging.`
			`pub fn print_page_allocations() {`
			`unsafe {`
			`let num_pages = (HEAP_SIZE - (ALLOC_START - HEAP_START)) / PAGE_SIZE;`
			`let mut beg = HEAP_START as *const Page;`
			`let end = beg.add(num_pages);`
			`let alloc_beg = ALLOC_START;`
			`let alloc_end = ALLOC_START + num_pages * PAGE_SIZE;`
			`println!();`
			`println!(`
			`"PAGE ALLOCATION TABLE\nMETA: {:p} -> {:p}\nPHYS: \`
			`0x{:x} -> 0x{:x}",`
			`beg, end, alloc_beg, alloc_end`
			`);`
			`println!("~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~");`
			`let mut num = 0;`
			`while beg < end {`
			`if (*beg).is_taken() {`
			`let start = beg as usize;`
			`let memaddr = ALLOC_START`
			`+ (start - HEAP_START)`
			`* PAGE_SIZE;`
			`print!("0x{:x} => ", memaddr);`
			`loop {`
			`num += 1;`
			`if (*beg).is_last() {`
			`let end = beg as usize;`
			`let memaddr = ALLOC_START`
			`+ (end`
			`- HEAP_START)`
			`* PAGE_SIZE`
			`+ PAGE_SIZE - 1;`
			`print!(`
			`"0x{:x}: {:>3} page(s)",`
			`memaddr,`
			`(end - start + 1)`
			`);`
			`println!(".");`
			`break;`
			`}`
			`beg = beg.add(1);`
			`}`
			`}`
			`beg = beg.add(1);`
			`}`
			`println!("~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~");`
			`println!(`
			`"Allocated: {:>6} pages ({:>10} bytes).",`
			`num,`
			`num * PAGE_SIZE`
			`);`
			`println!(`
			`"Free : {:>6} pages ({:>10} bytes).",`
			`num_pages - num,`
			`(num_pages - num) * PAGE_SIZE`
			`);`
			`println!();`
			`}`
			`}`

			`// ////////////////////////////////`
			`// // MMU Routines`
			`// ////////////////////////////////`

			`// Represent (repr) our entry bits as`
			`// unsigned 64-bit integers.`
			`#[repr(i64)]`
			`#[derive(Copy, Clone)]`
			`pub enum EntryBits {`
			`None = 0,`
			`Valid = 1 << 0,`
			`Read = 1 << 1,`
			`Write = 1 << 2,`
			`Execute = 1 << 3,`
			`User = 1 << 4,`
			`Global = 1 << 5,`
			`Access = 1 << 6,`
			`Dirty = 1 << 7,`

			`// Convenience combinations`
			`ReadWrite = 1 << 1 \| 1 << 2,`
			`ReadExecute = 1 << 1 \| 1 << 3,`
			`ReadWriteExecute = 1 << 1 \| 1 << 2 \| 1 << 3,`

			`// User Convenience Combinations`
			`UserReadWrite = 1 << 1 \| 1 << 2 \| 1 << 4,`
			`UserReadExecute = 1 << 1 \| 1 << 3 \| 1 << 4,`
			`UserReadWriteExecute = 1 << 1 \| 1 << 2 \| 1 << 3 \| 1 << 4,`
			`}`

			`// Helper functions to convert the enumeration`
			`// into an i64, which is what our page table`
			`// entries will be.`
			`impl EntryBits {`
			`pub fn val(self) -> i64 {`
			`self as i64`
			`}`
			`}`

			`// A single entry. We're using an i64 so that`
			`// this will sign-extend rather than zero-extend`
			`// since RISC-V requires that the reserved sections`
			`// take on the most significant bit.`
			`pub struct Entry {`
			`pub entry: i64,`
			`}`

			`// The Entry structure describes one of the 512 entries per table, which is`
			`// described in the RISC-V privileged spec Figure 4.18.`
			`impl Entry {`
			`pub fn is_valid(&self) -> bool {`
			`self.get_entry() & EntryBits::Valid.val() != 0`
			`}`

			`// The first bit (bit index #0) is the V bit for`
			`// valid.`
			`pub fn is_invalid(&self) -> bool {`
			`!self.is_valid()`
			`}`

			`// A leaf has one or more RWX bits set`
			`pub fn is_leaf(&self) -> bool {`
			`self.get_entry() & 0xe != 0`
			`}`

			`pub fn is_branch(&self) -> bool {`
			`!self.is_leaf()`
			`}`

			`pub fn set_entry(&mut self, entry: i64) {`
			`self.entry = entry;`
			`}`

			`pub fn get_entry(&self) -> i64 {`
			`self.entry`
			`}`
			`}`

			`// Table represents a single table, which contains 512 (2^9), 64-bit entries.`
			`pub struct Table {`
			`pub entries: [Entry; 512],`
			`}`

			`impl Table {`
			`pub fn len() -> usize {`
			`512`
			`}`
			`}`

			`/// Map a virtual address to a physical address using 4096-byte page`
			`/// size.`
			`/// root: a mutable reference to the root Table`
			`/// vaddr: The virtual address to map`
			`/// paddr: The physical address to map`
			`/// bits: An OR'd bitset containing the bits the leaf should have.`
			`/// The bits should contain only the following:`
			`/// Read, Write, Execute, User, and/or Global`
			`/// The bits MUST include one or more of the following:`
			`/// Read, Write, Execute`
			`/// The valid bit automatically gets added.`
			`pub fn map(root: &mut Table,`
			`vaddr: usize,`
			`paddr: usize,`
			`bits: i64,`
			`level: usize)`
			`{`
			`// Make sure that Read, Write, or Execute have been provided`
			`// otherwise, we'll leak memory and always create a page fault.`
			`assert!(bits & 0xe != 0);`
			`// Extract out each VPN from the virtual address`
			`// On the virtual address, each VPN is exactly 9 bits,`
			`// which is why we use the mask 0x1ff = 0b1_1111_1111 (9 bits)`
			`let vpn = [`
			`// VPN[0] = vaddr[20:12]`
			`(vaddr >> 12) & 0x1ff,`
			`// VPN[1] = vaddr[29:21]`
			`(vaddr >> 21) & 0x1ff,`
			`// VPN[2] = vaddr[38:30]`
			`(vaddr >> 30) & 0x1ff,`
			`];`

			`// Just like the virtual address, extract the physical address`
			`// numbers (PPN). However, PPN[2] is different in that it stores`
			`// 26 bits instead of 9. Therefore, we use,`
			`// 0x3ff_ffff = 0b11_1111_1111_1111_1111_1111_1111 (26 bits).`
			`let ppn = [`
			`// PPN[0] = paddr[20:12]`
			`(paddr >> 12) & 0x1ff,`
			`// PPN[1] = paddr[29:21]`
			`(paddr >> 21) & 0x1ff,`
			`// PPN[2] = paddr[55:30]`
			`(paddr >> 30) & 0x3ff_ffff,`
			`];`
			`// We will use this as a floating reference so that we can set`
			`// individual entries as we walk the table.`
			`let mut v = &mut root.entries[vpn[2]];`
			`// Now, we're going to traverse the page table and set the bits`
			`// properly. We expect the root to be valid, however we're required to`
			`// create anything beyond the root.`
			`// In Rust, we create a range iterator using the .. operator.`
			`// The .rev() will reverse the iteration since we need to start with`
			`// VPN[2] The .. operator is inclusive on start but exclusive on end.`
			`// So, (0..2) will iterate 0 and 1.`
			`for i in (level..2).rev() {`
			`if !v.is_valid() {`
			`// Allocate a page`
			`let page = zalloc(1);`
			`// The page is already aligned by 4,096, so store it`
			`// directly The page is stored in the entry shifted`
			`// right by 2 places.`
			`v.set_entry(`
			`(page as i64 >> 2)`
			`\| EntryBits::Valid.val(),`
			`);`
			`}`
			`let entry = ((v.get_entry() & !0x3ff) << 2) as *mut Entry;`
			`v = unsafe { entry.add(vpn[i]).as_mut().unwrap() };`
			`}`
			`// When we get here, we should be at VPN[0] and v should be pointing to`
			`// our entry.`
			`// The entry structure is Figure 4.18 in the RISC-V Privileged`
			`// Specification`
			`let entry = (ppn[2] << 28) as i64 \| // PPN[2] = [53:28]`
			`(ppn[1] << 19) as i64 \| // PPN[1] = [27:19]`
			`(ppn[0] << 10) as i64 \| // PPN[0] = [18:10]`
			`bits \| // Specified bits, such as User, Read, Write, etc`
			`EntryBits::Valid.val() \| // Valid bit`
			`EntryBits::Dirty.val() \| // Some machines require this to =1`
			`EntryBits::Access.val() // Just like dirty, some machines require this`
			`;`
			`// Set the entry. V should be set to the correct pointer by the loop`
			`// above.`
			`v.set_entry(entry);`
			`}`

			`/// Unmaps and frees all memory associated with a table.`
			`/// root: The root table to start freeing.`
			`/// NOTE: This does NOT free root directly. This must be`
			`/// freed manually.`
			`/// The reason we don't free the root is because it is`
			`/// usually embedded into the Process structure.`
			`pub fn unmap(root: &mut Table) {`
			`// Start with level 2`
			`for lv2 in 0..Table::len() {`
			`let ref entry_lv2 = root.entries[lv2];`
			`if entry_lv2.is_valid() && entry_lv2.is_branch() {`
			`// This is a valid entry, so drill down and free.`
			`let memaddr_lv1 = (entry_lv2.get_entry() & !0x3ff) << 2;`
			`let table_lv1 = unsafe {`
			`// Make table_lv1 a mutable reference instead of`
			`// a pointer.`
			`(memaddr_lv1 as *mut Table).as_mut().unwrap()`
			`};`
			`for lv1 in 0..Table::len() {`
			`let ref entry_lv1 = table_lv1.entries[lv1];`
			`if entry_lv1.is_valid() && entry_lv1.is_branch()`
			`{`
			`let memaddr_lv0 = (entry_lv1.get_entry()`
			`& !0x3ff) << 2;`
			`// The next level is level 0, which`
			`// cannot have branches, therefore,`
			`// we free here.`
			`dealloc(memaddr_lv0 as *mut u8);`
			`}`
			`}`
			`dealloc(memaddr_lv1 as *mut u8);`
			`}`
			`}`
			`}`

			`/// Walk the page table to convert a virtual address to a`
			`/// physical address.`
			`/// If a page fault would occur, this returns None`
			`/// Otherwise, it returns Some with the physical address.`
			`pub fn virt_to_phys(root: &Table, vaddr: usize) -> Option<usize> {`
			`// Walk the page table pointed to by root`
			`let vpn = [`
			`// VPN[0] = vaddr[20:12]`
			`(vaddr >> 12) & 0x1ff,`
			`// VPN[1] = vaddr[29:21]`
			`(vaddr >> 21) & 0x1ff,`
			`// VPN[2] = vaddr[38:30]`
			`(vaddr >> 30) & 0x1ff,`
			`];`

			`let mut v = &root.entries[vpn[2]];`
			`for i in (0..=2).rev() {`
			`if v.is_invalid() {`
			`// This is an invalid entry, page fault.`
			`break;`
			`}`
			`else if v.is_leaf() {`
			`// According to RISC-V, a leaf can be at any level.`

			`// The offset mask masks off the PPN. Each PPN is 9`
			`// bits and they start at bit #12. So, our formula`
			`// 12 + i * 9`
			`let off_mask = (1 << (12 + i * 9)) - 1;`
			`let vaddr_pgoff = vaddr & off_mask;`
			`let addr = ((v.get_entry() << 2) as usize) & !off_mask;`
			`return Some(addr \| vaddr_pgoff);`
			`}`
			`// Set v to the next entry which is pointed to by this`
			`// entry. However, the address was shifted right by 2 places`
			`// when stored in the page table entry, so we shift it left`
			`// to get it back into place.`
			`let entry = ((v.get_entry() & !0x3ff) << 2) as *const Entry;`
			`// We do i - 1 here, however we should get None or Some() above`
			`// before we do 0 - 1 = -1.`
			`v = unsafe { entry.add(vpn[i - 1]).as_ref().unwrap() };`
			`}`

			`// If we get here, we've exhausted all valid tables and haven't`
			`// found a leaf.`
			`None`
			`}`