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9 | bondari | 1 | <?xml version="1.0" encoding="UTF-8"?> |
39 | bondari | 2 | <chapter id="architecture"> |
3 | <?dbhtml filename="arch.html"?> |
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9 | bondari | 4 | |
131 | jermar | 5 | <title>Architecture Overview</title> |
37 | bondari | 6 | |
48 | jermar | 7 | <para>The HelenOS operating system is designed as a relatively small |
8 | microkernel assisted with a set of userspace drivers and server tasks. |
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138 | palkovsky | 9 | HelenOS is not very radical in which subsystems should or should not be |
48 | jermar | 10 | implemented in the kernel - in some cases, both kernel and userspace drivers |
11 | exist. The reason for creating the system as a microkernel is prosaic. Even |
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12 | though it is initially more difficult to get the same level of functionality |
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13 | from a microkernel than it is in the case of a simple monolithic kernel, a |
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14 | microkernel is much easier to maintain once the pieces have been put to work |
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15 | together. Therefore, the kernel of HelenOS, as well as the essential |
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16 | userspace libraries thereof can be maintained by only a few developers who |
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17 | understand them completely. In addition, a microkernel based operating |
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18 | system reaches completion sooner than monolithic kernels as the system can |
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19 | be used even without some traditional subsystems (e.g. block devices, |
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20 | filesystems and networking).</para> |
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38 | bondari | 21 | |
101 | bondari | 22 | <figure float="1"> |
87 | bondari | 23 | <mediaobject id="arch1"> |
24 | <imageobject role="pdf"> |
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126 | jermar | 25 | <imagedata fileref="images/arch1.pdf" format="PDF" /> |
77 | bondari | 26 | </imageobject> |
27 | |||
48 | jermar | 28 | <imageobject role="html"> |
29 | <imagedata fileref="images/arch1.png" format="PNG" /> |
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30 | </imageobject> |
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38 | bondari | 31 | |
48 | jermar | 32 | <imageobject role="fop"> |
105 | bondari | 33 | <imagedata fileref="images/arch1.svg" format="SVG" /> |
72 | bondari | 34 | </imageobject> |
62 | jermar | 35 | </mediaobject> |
72 | bondari | 36 | |
62 | jermar | 37 | <title>HelenOS architecture overview.</title> |
72 | bondari | 38 | </figure> |
48 | jermar | 39 | |
72 | bondari | 40 | <para>HelenOS is comprised of the kernel and the userspace server tasks. The |
48 | jermar | 41 | kernel provides scheduling, memory management and IPC. It also contains |
42 | essential device drivers that control the system clock and other devices |
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43 | necessary to guarantee a safe environment. Userspace communicates with the |
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44 | kernel through a small set of syscalls. The userspace layer consists of |
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45 | tasks with different roles, capabilities and privileges. Some of the tasks |
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46 | serve as device drivers, naming servers, managers of various kinds and some |
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47 | are just ordinary user programs. All of them communicate with other threads |
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48 | via kernel-provided IPC.</para> |
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49 | |||
39 | bondari | 50 | <section> |
48 | jermar | 51 | <title>Scheduling</title> |
38 | bondari | 52 | |
72 | bondari | 53 | <indexterm> |
54 | <primary>thread</primary> |
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55 | </indexterm> |
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56 | |||
48 | jermar | 57 | <para>Kernel's unit of execution flow is a thread. A thread is an entity |
58 | that executes code and has a stack that takes up some space in memory. The |
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59 | relation between kernel and userspace threads is 1:1:n, meaning that there |
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171 | jermar | 60 | can be several so called fibrils running within one userspace thread that |
48 | jermar | 61 | maps to one kernel thread. Threads are grouped into tasks by functionality |
62 | they provide (i.e. several threads implement functionality of one task). |
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72 | bondari | 63 | <indexterm> |
64 | <primary>task</primary> |
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65 | </indexterm> Tasks serve as containers of threads, they provide linkage |
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66 | to address space and are communication endpoints for IPC. Finally, tasks |
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67 | can be holders of capabilities that entitle them to do certain sensitive |
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58 | jermar | 68 | operations (e.g access raw hardware and physical memory).</para> |
48 | jermar | 69 | |
70 | <para>The scheduler deploys several run queues on each processor. A thread |
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71 | ready for execution is put into one of the run queues, depending on its |
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72 | priority and its current processor, from where it is eventually picked up |
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73 | by the scheduler. Special purpose kernel threads strive to keep processors |
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74 | balanced by thread migration. Threads are scheduled by the round robing |
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75 | scheduling policy with respect to multiple priority run queues.</para> |
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49 | jermar | 76 | </section> |
48 | jermar | 77 | |
49 | jermar | 78 | <section> |
131 | jermar | 79 | <title>Memory Management</title> |
49 | jermar | 80 | |
81 | <para>Memory management is another large subsystem in HelenOS. It serves |
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82 | the kernel to satisfy its own memory allocation requests, provides |
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83 | translation between virtual and physical memory addresses and manages |
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84 | virtual address spaces of userspace tasks.</para> |
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85 | |||
86 | <para>Kernel allocates memory from the slab allocator, which itself |
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87 | allocates memory from a buddy system based allocator of physical memory |
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88 | frames.</para> |
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89 | |||
90 | <para>The virtual address translation layer currently supports two |
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91 | mechanisms for mapping virtual memory pages to physical memory frames |
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92 | (i.e. 4-level hierarchical page tables and global page hash table), and is |
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93 | further extensible to other mechanisms.</para> |
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94 | |||
72 | bondari | 95 | <indexterm> |
96 | <primary>address space</primary> |
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97 | </indexterm> |
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98 | |||
49 | jermar | 99 | <para>Userspace tasks depend on support of address spaces provided by the |
138 | palkovsky | 100 | kernel. Each address space is a set of mutually disjunctive address space |
101 | areas. An address space area is usually connected to, and backed by, |
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102 | anonymous memory, executable image of some program or continuous region of |
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103 | physical memory. However, swapping pages in and out to external memory is |
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104 | not supported. Address space areas can be easily shared among address |
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105 | spaces.</para> |
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39 | bondari | 106 | </section> |
49 | jermar | 107 | |
108 | <section> |
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72 | bondari | 109 | <indexterm> |
110 | <primary>IPC</primary> |
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111 | </indexterm> |
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112 | |||
49 | jermar | 113 | <title>IPC</title> |
114 | |||
115 | <para>Due to the fact that HelenOS is a microkernel, strong emphasis is |
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116 | put on its IPC (Inter-Process Communication<footnote> |
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117 | <para>The term Inter-Process Communication is slightly confusing |
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118 | because in HelenOS terminology there are tasks instead of processes. |
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119 | However, its abbreviation, IPC, is being publicly used as a standard |
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120 | name for similar facilities. This book will therefore use the term IPC |
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121 | to refer to communication among tasks.</para> |
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122 | </footnote>). Tasks communicate by passing very short messages to one |
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123 | another or by sending (i.e. sharing) address space areas when larger data |
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124 | is to be transfered.</para> |
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125 | |||
72 | bondari | 126 | <indexterm> |
127 | <primary>IPC</primary> |
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128 | |||
129 | <secondary>- phone</secondary> |
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130 | </indexterm> |
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131 | |||
132 | <indexterm> |
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133 | <primary>IPC</primary> |
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134 | |||
135 | <secondary>- answerbox</secondary> |
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136 | </indexterm> |
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137 | |||
138 | <indexterm> |
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139 | <primary>IPC</primary> |
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140 | |||
141 | <secondary>- message queue</secondary> |
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142 | </indexterm> |
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143 | |||
49 | jermar | 144 | <para>The abstraction uses terms like phones, calls and answerboxes, but |
138 | palkovsky | 145 | is similar to well-known abstraction of message queues. A task can have |
146 | multiple simultaneous simplex connections to several other tasks. A |
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49 | jermar | 147 | connection leads from one of the source task's phones to the destination |
148 | task's answerbox. The phones are used as handles for making calls to other |
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138 | palkovsky | 149 | tasks. Calls are asynchronous and can be forwarded from one task to |
150 | another.</para> |
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49 | jermar | 151 | </section> |
138 | palkovsky | 152 | </chapter> |