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1 // Copyright (c) 2015 Sandstorm Development Group, Inc. and contributors
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2 // Licensed under the MIT License:
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3 //
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4 // Permission is hereby granted, free of charge, to any person obtaining a copy
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5 // of this software and associated documentation files (the "Software"), to deal
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6 // in the Software without restriction, including without limitation the rights
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7 // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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8 // copies of the Software, and to permit persons to whom the Software is
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9 // furnished to do so, subject to the following conditions:
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10 //
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11 // The above copyright notice and this permission notice shall be included in
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12 // all copies or substantial portions of the Software.
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13 //
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14 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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15 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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16 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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17 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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18 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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19 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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20 // THE SOFTWARE.
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21
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22 #ifndef CAPNP_MEMBRANE_H_
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23 #define CAPNP_MEMBRANE_H_
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24 // In capability theory, a "membrane" is a wrapper around a capability which (usually) forwards
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25 // calls but recursively wraps capabilities in those calls in the same membrane. The purpose of a
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26 // membrane is to enforce a barrier between two capabilities that cannot be bypassed by merely
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27 // introducing new objects.
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28 //
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29 // The most common use case for a membrane is revocation: Say Alice wants to give Bob a capability
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30 // to access Carol, but wants to be able to revoke this capability later. Alice can accomplish this
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31 // by wrapping Carol in a revokable wrapper which passes through calls until such a time as Alice
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32 // indicates it should be revoked, after which all calls through the wrapper will throw exceptions.
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33 // However, a naive wrapper approach has a problem: if Bob makes a call to Carol and sends a new
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34 // capability in that call, or if Carol returns a capability to Bob in the response to a call, then
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35 // the two are now able to communicate using this new capability, which Alice cannot revoke. In
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36 // order to avoid this problem, Alice must use not just a wrapper but a "membrane", which
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37 // recursively wraps all objects that pass through it in either direction. Thus, all connections
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38 // formed between Bob and Carol (originating from Alice's original introduction) can be revoked
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39 // together by revoking the membrane.
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40 //
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41 // Note that when a capability is passed into a membrane and then passed back out, the result is
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42 // the original capability, not a double-membraned capability. This means that in our revocation
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43 // example, if Bob uses his capability to Carol to obtain another capability from her, then send
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44 // it back to her, the capability Carol receives back will NOT be revoked when Bob's access to
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45 // Carol is revoked. Thus Bob can create long-term irrevocable connections. In most practical use
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46 // cases, this is what you want. APIs commonly rely on the fact that a capability obtained and then
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47 // passed back can be recognized as the original capability.
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48 //
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49 // Mark Miller on membranes: http://www.eros-os.org/pipermail/e-lang/2003-January/008434.html
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50
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51 #include "capability.h"
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52
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53 namespace capnp {
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54
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55 class MembranePolicy {
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56 // Applications may implement this interface to define a membrane policy, which allows some
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57 // calls crossing the membrane to be blocked or redirected.
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58
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59 public:
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60 virtual kj::Maybe<Capability::Client> inboundCall(
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61 uint64_t interfaceId, uint16_t methodId, Capability::Client target) = 0;
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62 // Given an inbound call (a call originating "outside" the membrane destined for an object
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63 // "inside" the membrane), decides what to do with it. The policy may:
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64 //
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65 // - Return null to indicate that the call should proceed to the destination. All capabilities
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66 // in the parameters or result will be properly wrapped in the same membrane.
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67 // - Return a capability to have the call redirected to that capability. Note that the redirect
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68 // capability will be treated as outside the membrane, so the params and results will not be
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69 // auto-wrapped; however, the callee can easily wrap the returned capability in the membrane
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70 // itself before returning to achieve this effect.
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71 // - Throw an exception to cause the call to fail with that exception.
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72 //
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73 // `target` is the underlying capability (*inside* the membrane) for which the call is destined.
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74 // Generally, the only way you should use `target` is to wrap it in some capability which you
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75 // return as a redirect. The redirect capability may modify the call in some way and send it to
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76 // `target`. Be careful to use `copyIntoMembrane()` and `copyOutOfMembrane()` as appropriate when
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77 // copying parameters or results across the membrane.
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78 //
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79 // Note that since `target` is inside the capability, if you were to directly return it (rather
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80 // than return null), the effect would be that the membrane would be broken: the call would
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81 // proceed directly and any new capabilities introduced through it would not be membraned. You
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82 // generally should not do that.
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83
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84 virtual kj::Maybe<Capability::Client> outboundCall(
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85 uint64_t interfaceId, uint16_t methodId, Capability::Client target) = 0;
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86 // Like `inboundCall()`, but applies to calls originating *inside* the membrane and terminating
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87 // outside.
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88 //
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89 // Note: It is strongly recommended that `outboundCall()` returns null in exactly the same cases
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90 // that `inboundCall()` return null. Conversely, for any case where `inboundCall()` would
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91 // redirect or throw, `outboundCall()` should also redirect or throw. Otherwise, you can run
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92 // into inconsistent behavion when a promise is returned across a membrane, and that promise
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93 // later resolves to a capability on the other side of the membrane: calls on the promise
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94 // will enter and then exit the membrane, but calls on the eventual resolution will not cross
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95 // the membrane at all, so it is important that these two cases behave the same.
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96
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97 virtual kj::Own<MembranePolicy> addRef() = 0;
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98 // Return a new owned pointer to the same policy.
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99 //
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100 // Typically an implementation of MembranePolicy should also inherit kj::Refcounted and implement
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101 // `addRef()` as `return kj::addRef(*this);`.
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102 //
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103 // Note that the membraning system considers two membranes created with the same MembranePolicy
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104 // object actually to be the *same* membrane. This is relevant when an object passes into the
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105 // membrane and then back out (or out and then back in): instead of double-wrapping the object,
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106 // the wrapping will be removed.
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107 };
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108
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109 Capability::Client membrane(Capability::Client inner, kj::Own<MembranePolicy> policy);
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110 // Wrap `inner` in a membrane specified by `policy`. `inner` is considered "inside" the membrane,
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111 // while the returned capability should only be called from outside the membrane.
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112
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113 Capability::Client reverseMembrane(Capability::Client outer, kj::Own<MembranePolicy> policy);
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114 // Like `membrane` but treat the input capability as "outside" the membrane, and return a
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115 // capability appropriate for use inside.
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116 //
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117 // Applications typically won't use this directly; the membraning code automatically sets up
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118 // reverse membranes where needed.
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119
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120 template <typename ClientType>
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121 ClientType membrane(ClientType inner, kj::Own<MembranePolicy> policy);
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122 template <typename ClientType>
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123 ClientType reverseMembrane(ClientType inner, kj::Own<MembranePolicy> policy);
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124 // Convenience templates which return the same interface type as the input.
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125
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126 template <typename ServerType>
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127 typename ServerType::Serves::Client membrane(
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128 kj::Own<ServerType> inner, kj::Own<MembranePolicy> policy);
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129 template <typename ServerType>
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130 typename ServerType::Serves::Client reverseMembrane(
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131 kj::Own<ServerType> inner, kj::Own<MembranePolicy> policy);
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132 // Convenience templates which input a capability server type and return the appropriate client
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133 // type.
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134
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135 template <typename Reader>
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136 Orphan<typename kj::Decay<Reader>::Reads> copyIntoMembrane(
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137 Reader&& from, Orphanage to, kj::Own<MembranePolicy> policy);
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138 // Copy a Cap'n Proto object (e.g. struct or list), adding the given membrane to any capabilities
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139 // found within it. `from` is interpreted as "outside" the membrane while `to` is "inside".
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140
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141 template <typename Reader>
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142 Orphan<typename kj::Decay<Reader>::Reads> copyOutOfMembrane(
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143 Reader&& from, Orphanage to, kj::Own<MembranePolicy> policy);
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144 // Like copyIntoMembrane() except that `from` is "inside" the membrane and `to` is "outside".
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145
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146 // =======================================================================================
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147 // inline implementation details
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148
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149 template <typename ClientType>
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150 ClientType membrane(ClientType inner, kj::Own<MembranePolicy> policy) {
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151 return membrane(Capability::Client(kj::mv(inner)), kj::mv(policy))
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152 .castAs<typename ClientType::Calls>();
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153 }
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154 template <typename ClientType>
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155 ClientType reverseMembrane(ClientType inner, kj::Own<MembranePolicy> policy) {
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156 return reverseMembrane(Capability::Client(kj::mv(inner)), kj::mv(policy))
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157 .castAs<typename ClientType::Calls>();
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158 }
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159
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160 template <typename ServerType>
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161 typename ServerType::Serves::Client membrane(
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162 kj::Own<ServerType> inner, kj::Own<MembranePolicy> policy) {
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163 return membrane(Capability::Client(kj::mv(inner)), kj::mv(policy))
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164 .castAs<typename ServerType::Serves>();
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165 }
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166 template <typename ServerType>
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167 typename ServerType::Serves::Client reverseMembrane(
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168 kj::Own<ServerType> inner, kj::Own<MembranePolicy> policy) {
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169 return reverseMembrane(Capability::Client(kj::mv(inner)), kj::mv(policy))
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170 .castAs<typename ServerType::Serves>();
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171 }
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172
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173 namespace _ { // private
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174
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175 OrphanBuilder copyOutOfMembrane(PointerReader from, Orphanage to,
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176 kj::Own<MembranePolicy> policy, bool reverse);
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177 OrphanBuilder copyOutOfMembrane(StructReader from, Orphanage to,
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178 kj::Own<MembranePolicy> policy, bool reverse);
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179 OrphanBuilder copyOutOfMembrane(ListReader from, Orphanage to,
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180 kj::Own<MembranePolicy> policy, bool reverse);
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181
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182 } // namespace _ (private)
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183
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184 template <typename Reader>
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185 Orphan<typename kj::Decay<Reader>::Reads> copyIntoMembrane(
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186 Reader&& from, Orphanage to, kj::Own<MembranePolicy> policy) {
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187 return _::copyOutOfMembrane(
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188 _::PointerHelpers<typename kj::Decay<Reader>::Reads>::getInternalReader(from),
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189 to, kj::mv(policy), true);
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190 }
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191
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192 template <typename Reader>
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193 Orphan<typename kj::Decay<Reader>::Reads> copyOutOfMembrane(
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194 Reader&& from, Orphanage to, kj::Own<MembranePolicy> policy) {
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195 return _::copyOutOfMembrane(
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196 _::PointerHelpers<typename kj::Decay<Reader>::Reads>::getInternalReader(from),
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197 to, kj::mv(policy), false);
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198 }
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199
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200 } // namespace capnp
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201
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202 #endif // CAPNP_MEMBRANE_H_
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